Evaluation and improvement of nuclease cleavage specificity

ABSTRACT

Engineered nucleases (e.g., zinc finger nucleases (ZFNs), transcriptional activator-like effector nucleases (TALENs), and others) are promising tools for genome manipulation and determining off-target cleavage sites of these enzymes is of great interest. We developed an in vitro selection method that interrogates 1011 DNA sequences for their ability to be cleaved by active, dimeric nucleases, e.g., ZFNs and TALENs. The method revealed hundreds of thousands of DNA sequences, some present in the human genome, that can be cleaved in vitro by two ZFNs, CCR5-224 and VF2468, which target the endogenous human CCR5 and VEGF-A genes, respectively. Our findings establish an energy compensation model of ZFN specificity in which excess binding energy contributes to off-target ZFN cleavage and suggest strategies for the improvement of future nuclease design. It was also observed that TALENs can achieve cleavage specificity similar to or higher than that observed in ZFNs.

RELATED APPLICATION

This application is a national stage filing under 35 U.S.C. § 371 of international PCT application, PCT/US2012/047778, filed Jul. 22, 2012, which claims priority under 35 U.S.C. § 119(e) to U.S. provisional patent application, U.S. Ser. No. 61/510,841, filed Jul. 22, 2011, the entire contents of each of which are incorporated herein by reference.

GOVERNMENT SUPPORT

This invention was made with government support under OD006862, GM065400 and BM088040 awarded by National Institutes of Health and HR0011-11-2-0003 awarded by Department of Defense. The government has certain rights in the invention.

BACKGROUND OF THE INVENTION

Site-specific endonucleases theoretically allow for the targeted manipulation of a single site within a genome, and are useful in the context of gene targeting as well as for therapeutic applications. In a variety of organisms, including mammals, site-specific endonucleases, for example, zinc-finger nucleases (ZFNs), have been used for genome engineering by stimulating either non-homologous end joining or homologous recombination. In addition to providing powerful research tools, ZFNs also have potential as gene therapy agents, and two ZFNs have recently entered clinical trials: one, CCR5-2246, targeting a human CCR-5 allele as part of an anti-HIV therapeutic approach (NCT00842634, NCT01044654, NCT01252641), and the other one, VF24684, targeting the human VEGF-A promoter as part of an anti-cancer therapeutic approach (NCT01082926).

Precise targeting of the intended target site is crucial for minimizing undesired off-target effects of site-specific nucleases, particularly in therapeutic applications, as imperfect specificity of some engineered site-specific binding domains has been linked to cellular toxicity. However, the site preferences for engineered site-specific nucleases, including current ZFNs, which cleave their target site after dimerization, has previously only been evaluated in vitro or in silico using methods that are limited to calculating binding and cleavage specificity for monomeric proteins.

Therefore, improved systems for evaluating the off-target sites of nucleases and other nucleic acid cleaving agents are needed and would be useful in the design of nucleases with better specificity, especially for therapeutic applications.

SUMMARY OF THE INVENTION

This invention is at least partly based on the recognition that the reported toxicity of some engineered site-specific endonucleases is based on off-target DNA cleavage, rather than on off-target binding alone. Information about the specificity of site-specific nucleases to date has been based on the assumptions that (i) dimeric nucleases cleave DNA with the same sequence specificity with which isolated monomeric domains bind DNA; and that (ii) the binding of one domain does not influence the binding of the other domain in a given dimeric nuclease. No study to date has reported a method for determining the broad DNA cleavage specificity of active, dimeric site-specific nucleases. Such a method would not only be useful in determining the DNA cleavage specificity of nucleases but would also find use in evaluating the cleavage specificity of other DNA cleaving agents, such as small molecules that cleave DNA.

This invention addresses the shortcomings of previous attempts to evaluate and characterize the sequence specificity of site-specific nucleases, and in particular of nucleases that dimerize or multimerize in order to cleave their target sequence. Some aspects of this invention provide an in vitro selection method to broadly examine the cleavage specificity of active nucleases. In some aspects, the invention provide methods of identifying suitable nuclease target sites that are sufficiently different from any other site within a genome to achieve specific cleavage by a given nuclease without any or at least minimal off-target cleavage. The invention provide methods of evaluating, selecting, and/or designing site specific nucleases with enhanced specificity as compared to current nucleases. Methods for minimizing off-target cleavage by a given nuclease, for example, by enhancing nuclease specificity by designing variant nucleases with binding domains having decreased binding affinity, by lowering the final concentration of the nuclease, and by choosing target sites that differ by at least three base pairs from their closest sequence relatives in the genome are provided. Compositions and kits useful in the practice of the inventive methods are also provided. The provided methods, compositions and kits are also useful in the evaluation, design, and selection of other nucleic acid (e.g., DNA) cleaving agents as would be appreciated by one of skill in the art.

In another aspect, the invention provides nucleases and other nucleic acid cleaving agents designed or selected using the provided system. Isolated ZFNs and TALENs designed, evaluated, or selected according to methods provided herein and pharmaceutical compositions comprising such nucleases are also provided.

Some aspects of this invention provide a method for identifying a target site of a nuclease. In some embodiments, the method comprises (a) providing a nuclease that cuts a double-stranded nucleic acid target site and creates a 5′ overhang, wherein the target site comprises a [left-half site]-[spacer sequence]-[right-half site] (LSR) structure, and the nuclease cuts the target site within the spacer sequence. In some embodiments, the method comprises (b) contacting the nuclease with a library of candidate nucleic acid molecules, wherein each nucleic acid molecule comprises a concatemer of a sequence comprising a candidate nuclease target site and a constant insert sequence, under conditions suitable for the nuclease to cut a candidate nucleic acid molecule comprising a target site of the nuclease. In some embodiments, the method comprises (c) filling in the 5′ overhangs of a nucleic acid molecule that has been cut twice by the nuclease and comprises a constant insert sequence flanked by a left half-site and cut spacer sequence on one side, and a right half-site and cut spacer sequence on the other side, thereby creating blunt ends. In some embodiments, the method comprises (d) identifying the nuclease target site cut by the nuclease by determining the sequence of the left-half site, the right-half-site, and/or the spacer sequence of the nucleic acid molecule of step (c). In some embodiments, determining the sequence of step (d) comprises ligating sequencing adapters to the blunt ends of the nucleic acid molecule of step (c) and amplifying and/or sequencing the nucleic acid molecule. In some embodiments, the method comprises amplifying the nucleic acid molecule after ligation of the sequencing adapters via PCR. In some embodiments, the method further comprises a step of enriching the nucleic acid molecules of step (c) or step (d) for molecules comprising a single constant insert sequence. In some embodiments, the step of enriching comprises a size fractionation. In some embodiments, the size fractionation is done by gel purification. In some embodiments, the method further comprises discarding any sequences determined in step (d) if the nucleic acid molecule did not comprise a complementary pair of filled-in 5′ overhangs. In some embodiments, the method further comprises compiling a plurality of nuclease target sites identified in step (d), thereby generating a nuclease target site profile. In some embodiments, the nuclease is a therapeutic nuclease which cuts a specific nuclease target site in a gene associated with a disease. In some embodiments, the method further comprises determining a maximum concentration of the therapeutic nuclease at which the therapeutic nuclease cuts the specific nuclease target site, and does not cut more than 10, more than 5, more than 4, more than 3, more than 2, more than 1, or no additional nuclease target sites. In some embodiments, the method further comprises administering the therapeutic nuclease to a subject in an amount effective to generate a final concentration equal or lower than the maximum concentration. In some embodiments, the nuclease comprises an unspecific nucleic acid cleavage domain. In some embodiments, the nuclease comprises a FokI cleavage domain. In some embodiments, the nuclease comprises a nucleic acid cleavage domain that cleaves a target sequence upon cleavage domain dimerization. In some embodiments, the nuclease comprises a binding domain that specifically binds a nucleic acid sequence. In some embodiments, the binding domain comprises a zinc finger. In some embodiments, the binding domain comprises at least 2, at least 3, at least 4, or at least 5 zinc fingers. In some embodiments, the nuclease is a Zinc Finger Nuclease. In some embodiments, the binding domain comprises a Transcriptional Activator-Like Element. In some embodiments, the nuclease is a Transcriptional Activator-Like Element Nuclease (TALEN). In some embodiments, the nuclease comprises an organic compound. In some embodiments, the nuclease comprises an enediyne. In some embodiments, the nuclease is an antibiotic. In some embodiments, the compound is dynemicin, neocarzinostatin, calicheamicin, esperamicin, bleomycin, or a derivative thereof. In some embodiments, the nuclease is a horning endonuclease.

Some aspects of this invention provide libraries of nucleic acid molecule. In some embodiments, a library of nucleic acid molecules is provided that comprises a plurality of nucleic acid molecules, wherein each nucleic acid molecule comprises a concatemer of a candidate nuclease target site and a constant insert sequence spacer sequence. In some embodiments, the candidate nuclease target site comprises a [left-half site]-[spacer sequence]-[right-half site] (LSR) structure. In some embodiments, the left-half site and/or the right-half site is between 10-18 nucleotides long. In some embodiments, the library comprises candidate nuclease target sites that can be cleaved by a nuclease comprising a FokI cleavage domain. In some embodiments, the library comprises candidate nuclease target sites that can be cleaved by a Zinc Finger Nuclease (ZFN), a Transcription Activator-Like Effector Nuclease (TALEN), a homing endonuclease, an organic compound nuclease, an enediyne, an antibiotic nuclease, dynemicin, neocarzinostatin, calicheamicin, esperamicin, and/or bleomycin. In some embodiments, the library comprises at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰, at least 10¹¹, or at least 10¹² different candidate nuclease target sites. In some embodiments, the library comprises nucleic acid molecules of a molecular weight of at least 5 kDa, at least 6 kDa, at least 7 kDa, at least 8 kDa, at least 9 kDa, at least 10 kDa, at least 12 kDa, or at least 15 kDa. In some embodiments, the candidate nuclease target sites comprise a partially randomized left-half site, a partially randomized right-half site, and/or a partially randomized spacer sequence. In some embodiments, the library is templated on a known target site of a nuclease of interest. In some embodiments, the nuclease of interest is a ZFN, a TALEN, a homing endonuclease, an organic compound nuclease, an enediyne, an antibiotic nuclease, dynemicin, neocarzinostatin, calicheamicin, esperamicin, bleomycin, or a derivative thereof. In some embodiments, partial randomized sites differ from the consensus site by more than 5%, more than 10%, more than 15%, more than 20%, more than 25%, or more than 30% on average, distributed binomially. In some embodiments, partial randomized sites differ from the consensus site by no more than 10%, no more than 15%, no more than 20%, no more than 25%, nor more than 30%, no more than 40%, or no more than 50% on average, distributed binomially. In some embodiments, the candidate nuclease target sites comprise a randomized spacer sequence.

Some aspects of this invention provide methods of selecting a nuclease based on an evaluation of cleavage specificity. In some embodiments, a method of selecting a nuclease that specifically cuts a consensus target site from a plurality of nucleases is provided. In some embodiments, the method comprises (a) providing a plurality of candidate nucleases that cut the same consensus sequence; (b) for each of the candidate nucleases of step (a), identifying a nuclease target site cleaved by the candidate nuclease that differ from the consensus target site; and (c) selecting a nuclease based on the nuclease target site(s) identified in step (b). In some embodiments, the nuclease selected in step (c) is the nuclease that cleaves the consensus target site with the highest specificity. In some embodiments, the nuclease that cleaves the consensus target site with the highest specificity is the candidate nuclease that cleaves the lowest number of target sites that differ from the consensus site. In some embodiments, the candidate nuclease that cleaves the consensus target site with the highest specificity is the candidate nuclease that cleaves the lowest number of target sites that are different from the consensus site in the context of a target genome. In some embodiments, the candidate nuclease selected in step (c) is a nuclease that does not cleave any target site other than the consensus target site. In some embodiments, the candidate nuclease selected in step (c) is a nuclease that does not cleave any target site other than the consensus target site within the genome of a subject at a therapeutically effective concentration of the nuclease. In some embodiments, the method further comprises contacting a genome with the nuclease selected in step (c). In some embodiments, the genome is a vertebrate, mammalian, human, non-human primate, rodent, mouse rat, hamster, goat, sheep, cattle, dog, cat, reptile, amphibian, fish, nematode, insect, or fly genome. In some embodiments, the genome is within a living cell. In some embodiments, the genome is within a subject. In some embodiments, the consensus target site is within an allele that is associated with a disease or disorder. In some embodiments, cleavage of the consensus target site results in treatment or prevention of the disease or disorder. In some embodiments, cleavage of the consensus target site results in the alleviation of a symptom of the disease or disorder. In some embodiments, the disease is HIV/AIDS, or a proliferative disease. In some embodiments, the allele is a CCR5 or VEGFA allele.

Some aspects of this invention provide a method for selecting a nuclease target site within a genome. In some embodiments, the method comprises (a) identifying a candidate nuclease target site; and (b) using a general purpose computer, comparing the candidate nuclease target site to other sequences within the genome, wherein if the candidate nuclease target site differs from any other sequence within the genome by at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9, or at least 10 nucleotides, selecting the candidate nuclease site. In some embodiments, the candidate nuclease target site comprises a [left-half site]-[spacer sequence]-[right-half site] (LSR) structure. In some embodiments, the left-half site and/or the right-half site is 10-18 nucleotides long. In some embodiments, the spacer is 10-24 nucleotides long. In some embodiments, the method further comprises designing and/or generating a nuclease targeting the candidate nuclease site selected in step (b). In some embodiments, designing and/or generating is done by recombinant technology. In some embodiments, designing and/or generating comprises designing a binding domain that specifically binds the selected candidate target site, or a half-site thereof. In some embodiments, designing and/or generating comprises conjugating the binding domain with a nucleic acid cleavage domain. In some embodiments, the nucleic acid cleavage domain is a non-specific cleavage domain and/or wherein the nucleic acid cleavage domain must dimerize or multimerize in order to cut a nucleic acid. In some embodiments, the nucleic acid cleavage domain comprises a FokI cleavage domain. In some embodiments, the method further comprises isolating the nuclease. In some embodiments, the nuclease is a Zinc Finger Nuclease (ZFN) or a Transcription Activator-Like Effector Nuclease (TALEN), a homing endonuclease, or is or comprises an organic compound nuclease, an enediyne, an antibiotic nuclease, dynemicin, neocarzinostatin, calicheamicin, esperamicin, bleomycin, or a derivative thereof. In some embodiments, the candidate target site is within a genomic sequence the cleavage of which is known to be associated with an alleviation of a symptom of a disease or disorder. In some embodiments, the disease is HIV/AIDS, or a proliferative disease. In some embodiments, the genomic sequence is a CCR5 or VEGFA sequence.

Some aspects of this invention provide isolated nucleases with enhanced specificity and nucleic acids encoding such nucleases. In some embodiments, an isolated nuclease is provided that has been engineered to cleave a target site within a genome, wherein the nuclease has been selected according to any of the selection methods described herein. In some embodiments, an isolated nuclease is provided that cuts a target site selected according to any of the methods described herein. In some embodiments, an isolated nuclease is provided that is designed or engineered according to any of the concepts or parameters described herein. In some embodiments, the nuclease is a Zinc Finger Nuclease (ZFN) or a Transcription Activator-Like Effector Nuclease (TALEN), a homing endonuclease, or is or comprises an organic compound nuclease, an enediyne, an antibiotic nuclease, dynemicin, neocarzinostatin, calicheamicin, esperamicin, bleomycin, or a derivative thereof.

Some aspects of this invention provide kits comprising nucleases and nuclease compositions. In some embodiments, a kit is provided that comprises an isolated nuclease described herein. In some embodiments, the kit further comprises a nucleic acid comprising a target site of the isolated nuclease. In some embodiments, the kit comprises an excipient and instructions for contacting the nuclease with the excipient to generate a composition suitable for contacting a nucleic acid with the nuclease. In some embodiments, the nucleic acid is a genome or part of a genome. In some embodiments, the genome is within a cell. In some embodiments, the genome is within a subject and the excipient is a pharmaceutically acceptable excipient.

Some aspects of this invention provide pharmaceutical compositions comprising a nuclease or a nucleic acid encoding a nuclease as described herein. In some embodiments, pharmaceutical composition for administration to a subject is provided. In some embodiments, the composition comprises an isolated nuclease described herein or a nucleic acid encoding such a nuclease and a pharmaceutically acceptable excipient.

Other advantages, features, and uses of the invention will be apparent from the detailed description of certain non-limiting embodiments; the drawings, which are schematic and not intended to be drawn to scale; and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1. In vitro selection for ZFN-mediated cleavage. Pre-selection library members are concatemers (represented by arrows) of identical ZFN target sites lacking 5′ phosphates. L=left half-site; R=right half-site, S=spacer; L′, S′, R′=complementary sequences to L, S, R. ZFN cleavage reveals a 5′ phosphate, which is required for sequencing adapter ligation. The only sequences that can be amplified by PCR using primers complementary to the adapters are sequences that have been cleaved twice and have adapters on both ends. DNA cleaved at adjacent sites are purified by gel electrophoresis and sequenced. A computational screening step after sequencing ensures that the filled-in spacer sequences (S and S′) are complementary and therefore from the same molecule.

FIG. 2. DNA cleavage sequence specificity profiles for CCR5-224 and VF2468 ZFNs. The heat maps show specificity scores compiled from all sequences identified in selections for cleavage of 14 nM of DNA library with (a) 2 nM CCR5-224 (SEQ ID NOs:1 and 2) or (b) 1 nM VF2468 (SEQ ID NOs:3 and 4). The target DNA sequence is shown below each half-site. Black boxes indicate target base pairs. Specificity scores were calculated by dividing the change in frequency of each base pair at each position in the post-selection DNA pool compared to the pre-selection pool by the maximal possible change in frequency from pre-selection library to post-selection library of each base pair at each position. Blue boxes indicate enrichment for a base pair at a given position, white boxes indicate no enrichment, and red boxes indicate enrichment against a base pair at a given position. The darkest blue shown in the legend corresponds to absolute preference for a given base pair (specificity score=1.0), while the darkest red corresponds to an absolute preference against a given base pair (specificity score=−1.0).

FIG. 3. Evidence for a compensation model of ZFN target site recognition. The heat maps show the changes in specificity score upon mutation at the black-boxed positions in selections with (a) 2 nM CCR5-224 (SEQ ID NOs:5-6) or (b) 1 nM VF2468. Each row corresponds to a different mutant position (explained graphically in FIG. 12). Sites are listed in their genomic orientation; the (+) half-site of CCR5-224 and the (+) half-site of VF2468 are therefore listed as reverse complements of the sequences found in FIG. 2. Shades of blue indicate increased specificity score (more stringency) when the black boxed position is mutated and shades of red indicate decreased specificity score (less stringency).

FIG. 4. ZFNs can cleave a large fraction of target sites with three or fewer mutations in vitro. The percentages of the sequences with one, two, or three mutations that are enriched for in vitro cleavage (enrichment factor>1) by the (a) CCR5-224 ZFN and (b) VF2468 ZFN are shown. Enrichment factors are calculated for each sequence identified in the selection by dividing the observed frequency of that sequence in the post-selection sequenced library by the frequency of that sequence in the pre-selection library.

FIG. 5. In vitro synthesis of target site library. Library members consist of a partially randomized left-half site (L), a fully randomized 4-7 nucleotide spacer sequence (S), and a partially randomized right-half site (R). Library members present on DNA primers were incorporated into a linear ˜545 base pair double-stranded DNA by PCR. During PCR, a primer with a library member (L S R) can anneal to a DNA strand with a different library member (L*S*R*), resulting in a double-strand DNA with two different library members at one end. The 3′-5′ exonuclease and 5′-3′ polymerase activities of T4 DNA polymerase removed mismatched library members and replaced them with complementary, matched library members (L′S′R′). After 5′ phosphorylation with T4 polynucleotide kinase, the library DNA was subjected to blunt-end ligation, resulting in a mixture of linear and circular monomeric and multimeric species. Circular monomers were purified by gel electrophoresis and concatenated through rolling-circle amplification with Φ29 DNA polymerase.

FIG. 6. Expression and quantification of ZFNs. Western blots for CCR5-224 and VF2468 are shown (a) for the ZFN samples used in the in vitro selection, and (b) for quantification. (c) Known quantities of N-terminal FLAG-tagged bacterial alkaline phosphatase (FLAG-BAP) were used to generate a standard curve for ZFN quantification. Diamonds represent the intensities of FLAG-BAP standards from the Western blot shown in (b), plus signs represent the intensities of bands of ZFNs, and the line shows the best-fit curve of FLAG-BAP standards that was used to quantify ZFNs. (d) Gels are shown of activity assays of CCR5-224 and VF2468 on an 8 nM linear substrate containing one target cleavage site. The ZFNs were each incubated with their respective substrate for 4 hours at 37° C. DNA in the “+lysate” lane was incubated with an amount of in vitro transcription/translation mixture equivalent to that used in the 2.5 nM ZFN reaction. ZFN-mediated cleavage results in two linear fragments approximately 700 bp and 300 bp in length. 2 nM CCR5-224 and 1 nM VF2468 were the amounts required for 50% cleavage of the linear substrate.

FIG. 7. Library cleavage with ZFNs. Cleavage of 1 μg of concatemeric libraries of CCR5-224 (a) or VF2468(b) target sites are shown with varying amounts CCR5-224 or VF2468, respectively. The lane labeled “+lysate” refers to pre-selection concatemeric library incubated with the volume of in vitro transcription/translation mixture contained in the samples containing 4 nM CCR5-224 or 4 nM of VF2468. Uncut DNA, which would be observed in the “+lysate” lane, is of length >12 kb and is lost upon purification due to its size and therefore is not present on the gel. The lane labeled “+PvuI” is a digest of the pre-selection library at PvuI sites introduced adjacent to library members. The laddering on the gels results from cleavage of pre-selection DNA concatemers at more than one site. There is a dose dependent increase in the amount of the bottom band, which corresponds to cleavage at two adjacent library sites in the same pre-selection DNA molecule. This bottom band of DNA was enriched by PCR and gel purification before sequencing.

FIG. 8. ZFN off-target cleavage is dependent on enzyme concentration. For both (a) CCR5-224 and (b) VF2468 the distribution of cleavable sites revealed by in vitro selection shifts to include sites that are less similar to the target site as the concentration of ZFN increases. Both CCR5-224 and VF2468 selections enrich for sites that have fewer mutations than the pre-selection library. For comparisons between preselection and post-selection library means for all combinations of selection stringencies, P-values are 0 with the exception of the comparison between 0.5 nM and 1 nM VF2468 selections, which has a P-value of 1.7×10⁻¹⁴.

FIG. 9. Cleavage efficiency of individual sequences is related to selection stringency. In vitro DNA digests were performed on sequences identified in selections of varying stringencies (marked with ‘X’s). 2 nM CCR5-224 (SEQ ID NOs:7-14) (a) or 1 nM VF2468 (SEQ ID NOs:15-24) (b) was incubated with 8 nM of linear substrate containing the sequence shown. The 1 kb linear substrate contained a single cleavage site with the spacer sequence found in the genomic target of CCR5-224 (“CTGAT”) or VF2468 (“TCGAA”) and the indicated (+) and (−) half-sites. Mutant base pairs are represented with lowercase letters. CCR5-224 sites and VF2468 sites that were identified in the highest stringency selections (0.5 nM ZFN) are cleaved most efficiently, while sites that were identified only in the lowest stringency selections (4 nM ZFN) are cleaved least efficiently.

FIG. 10. Concentration-dependent sequence profiles for CCR5-224 and VF2468 ZFNs. The heat maps show specificity scores for the cleavage of 14 nM of total DNA library with varying amounts of CCR5-224 (FIGS. 10a and 10b ) or VF2468 (FIGS. 10c and 10d ). The target DNA sequence is shown below each half-site. Black boxes indicate target base pairs. Specificity scores were calculated by dividing the change in frequency of each base pair at each position in the post-selection DNA pool compared to the pre-selection pool by the maximal possible change in frequency of each base pair at each position. Blue boxes indicate specificity for a base pair at a given position, white boxes indicate no specificity, and red boxes indicate specificity against a base pair at a given position. The darkest blue shown in the legend corresponds to absolute preference for a given base pair (specificity score=1.0), while the darkest red corresponds to an absolute preference against a given base pair (specificity score=−1.0).

FIG. 11. Stringency at the (+) half-site increases when CCR5-224 cleaves sites with mutations at highly specified base pairs in the (−) half-site. The heat maps show specificity scores for sequences (SEQ ID NOs:29 and 30) identified in the in vitro selection with 2 nM CCR5-224. For (−)A3 and (−)G6, indicated by filled black boxes, both pre-selection library sequences and post-selection sequences were filtered to exclude any sequences that contained an A at position 3 in the (−) half-site or G at position 6 in the (−) half-site, respectively, before specificity scores were calculated. For sites with either (−) half-site mutation, there is an increase in specificity at the (+) half-site. Black boxes indicate target base pairs. Specificity scores were calculated by dividing the change in frequency of each base pair at each position in the post-selection DNA pool compared to the pre-selection pool by the maximal possible change in frequency of each base pair at each position. Blue boxes indicate specificity for a base pair at a given position, white boxes indicate no specificity, and red boxes indicate specificity against a base pair at a given position. The darkest blue shown in the legend corresponds to absolute preference for a given base pair (specificity score=1.0), while the darkest red corresponds to an absolute preference against a given base pair (specificity score=−1.0).

FIG. 12. Data processing steps used to create mutation compensation difference maps (SEQ ID NOs:31-39). The steps to create each line of the difference map in FIG. 3 are shown for the example of a mutation at position (−)A3. (a) Heat maps of the type described in FIG. 11 are condensed into one line to show only the specificity scores for intended target site nucleotides (in black outlined boxes in FIG. 11). (b) The condensed heat maps are then compared to a condensed heat map corresponding to the unfiltered baseline profile from FIG. 2, to create a condensed difference heat map that shows the relative effect of mutation at the position specified by the white box with black outline on the specificity score profile. Blue boxes indicate an increase in sequence stringency at positions in cleaved sites that contain mutations at the position indicated by the white box, while red boxes indicate a decrease in sequence stringency and white boxes, no change in sequence stringency. The (+) half-site difference map is reversed to match the orientation of the (+) half-site as it is found in the genome rather than as it is recognized by the zinc finger domain of the ZFN.

FIG. 13. Stringency at both half-sites increases when VF2468 cleaves sites with mutations at the first base pair of both half-sites. The heat maps show specificity scores for sequences identified in the in vitro selection with 4 nM VF2468. For (+)G1, (−)G1 (SEQ ID NO:40), and (+)G1/(−)G1 (SEQ ID NO:41), indicated by filled black boxes, both pre-selection library sequences and post-selection sequences were filtered to exclude any sequences that contained an G at position 1 in the (+) half-site and/or G at position 1 in the (−) half-site, before specificity scores were calculated. For sites with either mutation, there is decrease in mutational tolerance at the opposite half-site and a very slight decrease in mutational tolerance at the same half-site. Sites with both mutations show a strong increase in stringency at both half-sites. Black boxes indicate on-target base pairs. Specificity scores were calculated by dividing the change in frequency of each base pair at each position in the post-selection DNA pool compared to the pre-selection pool by the maximal possible change in frequency of each base pair at each position. Blue boxes indicate specificity for a base pair at a given position, white boxes indicate no specificity, and red boxes indicate specificity against a base pair at a given position. The darkest blue shown in the legend corresponds to absolute preference for a given base pair (specificity score=1.0), while the darkest red corresponds to an absolute preference against a given base pair (specificity score=−1.0).

FIG. 14. ZFN cleavage occurs at characteristic locations in the DNA target site. The plots show the locations of cleavage sites identified in the in vitro selections with (a) 4 nM CCR5-224 or (b) 4 nM VF2468. The cleavage site locations show similar patterns for both ZFNs except in the case of five-base pair spacers with four-base overhangs. The titles refer to the spacer length/overhang length combination that is plotted (e.g., a site with a six base-pair spacer and a four base overhang is referred to as “6/4”). The black bars indicate the relative number of sequences cleaved for each combination of spacer length and overhang length. ‘P’ refers to nucleotides in the (+) target half-site, ‘M’ refers to nucleotides in the (−) target half site, and ‘N’ refers to nucleotides in the spacer. There were no “7/7” sequences from the 4 nM VF2468 selection. Only sequences with overhangs of at least 4 bases were tabulated.

FIG. 15. CCR5-224 preferentially cleaves five- and six-base pair spacers and cleaves five-base pair spacers to leave five-nucleotide overhangs. The heat maps show the percentage of all sequences surviving each of the four CCR5-224 in vitro selections (a-d) that have the spacer and overhang lengths shown.

FIG. 16. VF2468 preferentially cleaves five- and six-base pair spacers, cleaves five-base pair spacers to leave five-nucleotide overhangs, and cleaves six-base pair spacers to leave four-nucleotide overhangs. The heat maps show the percentage of all sequences surviving each of the four VF2468 in vitro selections (a-d) that have the spacer and overhang lengths shown.

FIG. 17. ZFNs show spacer length-dependent sequence preferences. Both CCR5-224 (a-c) and VF2468 (d-f) show increased specificity for half-sites flanking four- and seven-base pair spacers than for half-sites flanking five- and six-base pair spacers. For both ZFNs, one half-site has a greater change in mutational tolerance than the other, and the change in mutational tolerance is concentration dependent.

FIG. 18. Model for ZFN tolerance of off-target sequences. Our results suggest that some ZFNs recognize their intended target sites (top, black DNA strands with no Xs) with more binding energy than is required for cleavage under a given set of conditions (dotted line). Sequences with one or two mutations (one or two Xs) are generally tolerated since they do not decrease the ZFN:DNA binding energy below the threshold necessary for cleavage. Some sequences with additional mutations can still be cleaved if the additional mutations occur in regions of the zinc-finger binding interface that have already been disrupted (three Xs above the dotted line), as long as optimal interactions present at other locations in the ZFN:DNA binding interface maintain binding energies above threshold values. Additional mutations that disrupt key interactions at other locations in the ZFN:DNA interface, however, result in binding energies that fall short of the cleavage threshold.

FIG. 19. Profiling The Specificity of TAL Nucleases. Selection 1: +28 vs. +63 aa Linker Between TAL DNA Binding Domain and Fok1 Cleavage Domain (SEQ ID NOs:42-45).

FIG. 20. Structure of TAL DNA binding domain and RVDs (SEQ ID NOs:46 and 47).

FIG. 21. Mutations in target sites from TALN selection. The +28 linker enriched for cleaved sequences with less mutations suggesting the +28 linker is more specific. There are significantly less mutations in the post-selected sequences compared to the pre-selection library sequences indicating a successful selection

FIG. 22. Enrichment of Mutations in Total Target Site Between Left and Right Half Sites of Previous TALN Selection. The relatively regular (log relationship) trend between number of half sites mutations and enrichment is consistent with a single repeat binding a base pair independent of other repeat binding.

FIG. 23. TALN Cleavage Dependence on DNA Spacer Length. There is a similar preference for cut site spacer lengths in our in vitro selection compared to previous studies. In vitro. TALN cleavage. Dependence on Linker Length & Spacer Length from Mussolino (2011).

FIG. 24. Specificity score at individual bases.

FIG. 25. Specificity score at individual bases. There is variable specificity at each individual position again with +28 linker demonstrating significantly better specificity (SEQ ID NOs:48 and 49).

FIG. 26. Compensating Difference in Specificity of TALNs Analysis (SEQ ID NOs:50-51).

FIG. 27. Compensating Difference in Specificity of L16 R16 TALN. A single mutation in the cleavage site does not alter the distribution of other mutations suggesting that the TAL repeat domains bind independently (SEQ ID NOs:52-53).

FIG. 28. Profiling the Specificity of TALNs Selection II: Varying TALN Lengths (SEQ ID NOs:54-61).

FIG. 29. Enrichment of Mutations in Common Target Site (SEQ ID NOs:62-69).

FIG. 30. Distribution of Mutations in Total Targeted Site of TALN Digestion vs. Pre-Selection Library.

FIG. 31. Distribution of Mutations in Total Targeted Site of TALN Digestion vs. Pre-Selection Library.

FIG. 32. Enrichment of Mutations in Total Target Site Between Right and Left Half Sites of TALN Pairs.

FIG. 33. Enrichment of Mutations in Total Target Site Between Right and Left Half Sites of TALN Pairs.

FIG. 34. Enrichment of Mutations in Total Targeted Site of TALN Digestion vs. Pre-Selection Library for L10 R10 TALN Pair.

FIG. 35. DNA spacer profile. While the vast majority of sequences have a spacer preference, the highly mutant sequences have no significant spacer preference as might be expected from alternate frames changing the spacer length.

FIG. 36. Cleavage point profile. While the vast majority of sequences are cut in the spacer as expected, the R16 L16 highly mutant sequences are not predominately cut in spacer but the L10 R10 ones are cut in the spacer possibly indicative of a frame-shifted binding site leading to productive spacer cutting.

FIG. 37. Highly Mutant Half Sites in L10 R10 TALN Pair. Many potential binding sites in frames outside of the intended frame have sites more similar to the intended target (SEQ ID NOs:70-90).

FIG. 38. Enrichment of Mutations in Total Target Site Between Left and Right Half Sites of TALN Pairs Edited for Frame-shifted Binding Sites.

FIG. 39. Highly Mutant Half Sites in L16 R16 TALN Pair (SEQ ID NOs:91-111).

FIG. 40. Highly Mutant Half Sites in L16 R16 TALN Pair. The highly mutant sequences from L16 R16 cannot be explained by a frame-shift (left figure), have no DNA Spacer preference (see slide 11) and seem to be cutting more often outside of the DNA Spacer (right figure) indicating perhaps homodimer cleavage (even with heterodimer) or heterodimer cleavage independent of a TAL domain binding target site DNA (i.e. dimerization through the Fok1 cleavage domain).

FIG. 41. Heat Maps of TALN Pair Specificity Score (SEQ ID NOs:112 and 113).

FIG. 42. Compensating Difference in Specificity of L16 R16 TALN. A single mutation in the cleavage site does not alter the distribution of other mutations suggesting that the TAL repeat domains bind independently (SEQ ID NOs:114 and 115).

FIG. 43. Enrichment of Mutations in Full, Total Target Site of TALN Pairs. The enrichments seem to have similar log slopes in the low mutation range, the selections containing a TALN recognizing 16 bps seem to be the exceptions indicating R16 binding may be saturating for some very low mutation sites (aka R16 & L16 were near or above the Kd for the wild type site).

FIG. 44. TALN Off-Target Sites in the Human Genome.

FIG. 45. TALN Off-Target Sites Predicted Cleavage.

FIG. 46. TALN Off-Target Sites Predicted Cleavage For Very Mutant Target Sites below Detection Limit.

FIG. 47. TALN Off-Target Sites Predicted Cleavage For Very Mutant Target Sites below Detection Limit.

FIG. 48. TALN Off-Target Sites Predicted Cleavage For Sequences (Not just Number of Mutations). Combining the regular log decrease of cleavage efficiency (enrichment) as total target site mutations increase and the enrichment at each position we should be able to predict the off-target site cleavage of any sequence (SEQ ID NOs:116-118).

FIG. 49. Comparing TALNs vs. ZFNs. For the most part, in the TALN selection the enrichment is dependent on the total mutations in both half sites and not on the distribution of mutations between half sites like for zinc finger nucleases (ZFN). This observation combined with the context dependent binding of ZFNs potentially make ZFN far less specific than their TAL equivalents.

DEFINITIONS

As used herein and in the claims, the singular forms “a,” “an,” and “the” include the singular and the plural reference unless the context clearly indicates otherwise. Thus, for example, a reference to “an agent” includes a single agent and a plurality of such agents.

The term “concatemer,” as used herein in the context of nucleic acid molecules, refers to a nucleic acid molecule that contains multiple copies of the same DNA sequences linked in a series. For example, a concatemer comprising ten copies of a specific sequence of nucleotides (e.g., [XYZ]₁₀), would comprise ten copies of the same specific sequence linked to each other in series, e.g., 5′-XYZXYZXYZXYZXYZXYZXYZXYZXYZXYZ-3′. A concatemer may comprise any number of copies of the repeat unit or sequence, e.g., at least 2 copies, at least 3 copies, at least 4 copies, at least 5 copies, at least 10 copies, at least 100 copies, at least 1000 copies, etc. An example of a concatemer of a nucleic acid sequence comprising a nuclease target site and a constant insert sequence would be [(target site)-(constant insert sequence)]₃₀₀. A concatemer may be a linear nucleic acid molecule, or may be circular.

The terms “conjugating,” “conjugated,” and “conjugation” refer to an association of two entities, for example, of two molecules such as two proteins, two domains (e.g., a binding domain and a cleavage domain), or a protein and an agent, e.g., a protein binding domain and a small molecule. The association can be, for example, via a direct or indirect (e.g., via a linker) covalent linkage or via non-covalent interactions. In some embodiments, the association is covalent. In some embodiments, two molecules are conjugated via a linker connecting both molecules. For example, in some embodiments where two proteins are conjugated to each other, e.g., a binding domain and a cleavage domain of an engineered nuclease, to form a protein fusion, the two proteins may be conjugated via a polypeptide linker, e.g., an amino acid sequence connecting the C-terminus of one protein to the N-terminus of the other protein.

The term “consensus sequence,” as used herein in the context of nucleic acid sequences, refers to a calculated sequence representing the most frequent nucleotide residues found at each position in a plurality of similar sequences. Typically, a consensus sequence is determined by sequence alignment in which similar sequences are compared to each other and similar sequence motifs are calculated. In the context of nuclease target site sequences, a consensus sequence of a nuclease target site may, in some embodiments, be the sequence most frequently bound, or bound with the highest affinity, by a given nuclease.

The term “effective amount,” as used herein, refers to an amount of a biologically active agent that is sufficient to elicit a desired biological response. For example, in some embodiments, an effective amount of a nuclease may refer to the amount of the nuclease that is sufficient to induce cleavage of a target site specifically bound and cleaved by the nuclease. As will be appreciated by the skilled artisan, the effective amount of an agent, e.g., a nuclease, a hybrid protein, or a polynucleotide, may vary depending on various factors as, for example, on the desired biological response, the specific allele, genome, target site, cell, or tissue being targeted, and the agent being used.

The term “enediyne,” as used herein, refers to a class of bacterial natural products characterized by either nine- and ten-membered rings containing two triple bonds separated by a double bond (see, e.g., K. C. Nicolaou; A. L. Smith; E. W. Yue (1993). “Chemistry and biology of natural and designed enediynes”. PNAS 90 (13): 5881-5888; the entire contents of which are incorporated herein by reference). Some enediynes are capable of undergoing Bergman cyclization, and the resulting diradical, a 1,4-dehydrobenzene derivative, is capable of abstracting hydrogen atoms from the sugar backbone of DNA which results in DNA strand cleavage (see, e.g., S. Walker; R. Landovitz; W. D. Ding; G. A. Ellestad; D. Kahne (1992). “Cleavage behavior of calicheamicin gamma 1 and calicheamicin T”. Proc Natl Acad Sci U.S.A. 89 (10): 4608-12; the entire contents of which are incorporated herein by reference). Their reactivity with DNA confers an antibiotic character to many enediynes, and some enediynes are clinically investigated as anticancer antibiotics. Nonlimiting examples of enediynes are dynemicin, neocarzinostatin, calicheamicin, esperamicin (see, e.g., Adrian L. Smith and K. C. Bicolaou, “The Enediyne Antibiotics” J. Med. Chem., 1996, 39 (11), pp 2103-2117; and Donald Borders, “Enediyne antibiotics as antitumor agents,” Informa Healthcare; 1^(st) edition (Nov. 23, 1994, ISBN-10: 0824789385; the entire contents of which are incorporated herein by reference).

The term “homing endonuclease,” as used herein, refers to a type of restriction enzymes typically encoded by introns or inteins Edgell D R (February 2009). “Selfish DNA: homing endonucleases find a home”. Curr Biol 19 (3): R115-R117; Jasin M (June 1996). “Genetic manipulation of genomonth with rare-cutting endonucleases”. Trends Genet 12 (6): 224-8; Burt A, Koufopanou V (December 2004). “Homing endonuclease genes: the rise and fall and rise again of a selfish element”. Curr Opin Genet Dev 14 (6): 609-15; the entire contents of which are incorporated herein by reference. Homing endonuclease recognition sequences are long enough to occur randomly only with a very low probability (approximately once every 7×10¹⁰ bp), and are normally found in only one instance per genome.

The term “library,” as used herein in the context of nucleic acids or proteins, refers to a population of two or more different nucleic acids or proteins, respectively. For example, a library of nuclease target sites comprises at least two nucleic acid molecules comprising different nuclease target sites. In some embodiments, a library comprises at least 10¹, at least 10², at least 10³, at least 10⁴, at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰, at least 10¹¹, at least 10¹², at least 10¹³, at least 10¹⁴, or at least 10¹⁵ different nucleic acids or proteins. In some embodiments, the members of the library may comprise randomized sequences, for example, fully or partially randomized sequences. In some embodiments, the library comprises nucleic acid molecules that are unrelated to each other, e.g., nucleic acids comprising fully randomized sequences. In other embodiments, at least some members of the library may be related, for example, they may be variants or derivatives of a particular sequence, such as a consensus target site sequence.

The term “linker,” as used herein, refers to a chemical group or a molecule linking two adjacent molecules or moieties, e.g., a binding domain and a cleavage domain of a nuclease. Typically, the linker is positioned between, or flanked by, two groups, molecules, or other moieties and connected to each one via a covalent bond, thus connecting the two. In some embodiments, the linker is an amino acid or a plurality of amino acids (e.g., a peptide or protein). In some embodiments, the linker is an organic molecule, group, polymer, or chemical moiety.

The term “nuclease,” as used herein, refers to an agent, for example a protein or a small molecule, capable of cleaving a phosphodiester bond connecting nucleotide residues in a nucleic acid molecule. In some embodiments, a nuclease is a protein, e.g., an enzyme that can bind a nucleic acid molecule and cleave a phosphodiester bond connecting nucleotide residues within the nucleic acid molecule. A nuclease may be an endonuclease, cleaving a phosphodiester bonds within a polynucleotide chain, or an exonuclease, cleaving a phosphodiester bond at the end of the polynucleotide chain. In some embodiments, a nuclease is a site-specific nuclease, binding and/or cleaving a specific phosphodiester bond within a specific nucleotide sequence, which is also referred to herein as the “recognition sequence,” the “nuclease target site,” or the “target site.” In some embodiments, a nuclease recognizes a single stranded target site, while in other embodiments, a nuclease recognizes a double-stranded target site, for example a double-stranded DNA target site. The target sites of many naturally occurring nucleases, for example, many naturally occurring DNA restriction nucleases, are well known to those of skill in the art. In many cases, a DNA nuclease, such as EcoRI, HindIII, or BamHI, recognize a palindromic, double-stranded DNA target site of 4 to 10 base pairs in length, and cut each of the two DNA strands at a specific position within the target site. Some endonucleases cut a double-stranded nucleic acid target site symmetrically, i.e., cutting both strands at the same position so that the ends comprise base-paired nucleotides, also referred to herein as blunt ends. Other endonucleases cups a double-stranded nucleic acid target sites asymmetrically, i.e., cutting each strand at a different position so that the ends comprise unpaired nucleotides. Unpaired nucleotides at the end of a double-stranded DNA molecule are also referred to as “overhangs,” e.g., as “5′-overhang” or as “3′-overhang,” depending on whether the unpaired nucleotide(s) form(s) the 5′ or the 5′ end of the respective DNA strand. Double-stranded DNA molecule ends ending with unpaired nucleotide(s) are also referred to as sticky ends, as they can “stick to” other double-stranded DNA molecule ends comprising complementary unpaired nucleotide(s). A nuclease protein typically comprises a “binding domain” that mediates the interaction of the protein with the nucleic acid substrate, and also, in some cases, specifically binds to a target site, and a “cleavage domain” that catalyzes the cleavage of the phosphodiester bond within the nucleic acid backbone. In some embodiments a nuclease protein can bind and cleave a nucleic acid molecule in a monomeric form, while, in other embodiments, a nuclease protein has to dimerize or multimerize in order to cleave a target nucleic acid molecule. Binding domains and cleavage domains of naturally occurring nucleases, as well as modular binding domains and cleavage domains that can be fused to create nucleases binding specific target sites, are well known to those of skill in the art. For example, zinc fingers or transcriptional activator like elements can be used as binding domains to specifically bind a desired target site, and fused or conjugated to a cleavage domain, for example, the cleavage domain of FokI, to create an engineered nuclease cleaving the target site.

The terms “nucleic acid” and “nucleic acid molecule,” as used herein, refers to a compound comprising a nucleobase and an acidic moiety, e.g., a nucleoside, a nucleotide, or a polymer of nucleotides. Typically, polymeric nucleic acids, e.g., nucleic acid molecules comprising three or more nucleotides are linear molecules, in which adjacent nucleotides are linked to each other via a phosphodiester linkage. In some embodiments, “nucleic acid” refers to individual nucleic acid residues (e.g. nucleotides and/or nucleosides). In some embodiments, “nucleic acid” refers to an oligonucleotide chain comprising three or more individual nucleotide residues. As used herein, the terms “oligonucleotide” and “polynucleotide” can be used interchangeably to refer to a polymer of nucleotides (e.g., a string of at least three nucleotides). In some embodiments, “nucleic acid” encompasses RNA as well as single and/or double-stranded DNA. Nucleic acids may be naturally occurring, for example, in the context of a genome, a transcript, an mRNA, tRNA, rRNA, siRNA, snRNA, a plasmid, cosmid, chromosome, chromatid, or other naturally occurring nucleic acid molecule. On the other hand, a nucleic acid molecule may be a non-naturally occurring molecule, e.g., a recombinant DNA or RNA, an artificial chromosome, an engineered genome, or fragment thereof, or a synthetic DNA, RNA, DNA/RNA hybrid, or including non-naturally occurring nucleotides or nucleosides. Furthermore, the terms “nucleic acid,” “DNA,” “RNA,” and/or similar terms include nucleic acid analogs, i.e. analogs having other than a phosphodiester backbone. Nucleic acids can be purified from natural sources, produced using recombinant expression systems and optionally purified, chemically synthesized, etc. Where appropriate, e.g., in the case of chemically synthesized molecules, nucleic acids can comprise nucleoside analogs such as analogs having chemically modified bases or sugars, and backbone modifications' A nucleic acid sequence is presented in the 5′ to 3′ direction unless otherwise indicated. In some embodiments, a nucleic acid is or comprises natural nucleosides (e.g. adenosine, thymidine, guanosine, cytidine, uridine, deoxyadenosine, deoxythymidine, deoxyguanosine, and deoxycytidine); nucleoside analogs (e.g., 2-aminoadenosine, 2-thiothymidine, inosine, pyrrolo-pyrimidine, 3-methyl adenosine, 5-methylcytidine, 2-aminoadenosine, C5-bromouridine, C5-fluorouridine, C5-iodouridine, C5-propynyl-uridine, C5-propynyl-cytidine, C5-methylcytidine, 2-aminoadenosine, 7-deazaadenosine, 7-deazaguanosine, 8-oxoadenosine, 8-oxoguanosine, O(6)-methylguanine, and 2-thiocytidine); chemically modified bases; biologically modified bases (e.g., methylated bases); intercalated bases; modified sugars (e.g., 2′-fluororibose, ribose, 2′-deoxyribose, arabinose, and hexose); and/or modified phosphate groups (e.g., phosphorothioates and 5′-N-phosphoramidite linkages).

The term “pharmaceutical composition,” as used herein, refers to a composition that can be administrated to a subject in the context of treatment of a disease or disorder. In some embodiments, a pharmaceutical composition comprises an active ingredient, e.g. a nuclease or a nucleic acid encoding a nuclease, and a pharmaceutically acceptable excipient.

The term “proliferative disease,” as used herein, refers to any disease in which cell or tissue homeostasis is disturbed in that a cell or cell population exhibits an abnormally elevated proliferation rate. Proliferative diseases include hyperproliferative diseases, such as pre-neoplastic hyperplastic conditions and neoplastic diseases. Neoplastic diseases are characterized by an abnormal proliferation of cells and include both benign and malignant neoplasias. Malignant neoplasia is also referred to as cancer.

The terms “protein,” “peptide,” and “polypeptide” are used interchangeably herein, and refer to a polymer of amino acid residues linked together by peptide (amide) bonds. The terms refer to a protein, peptide, or polypeptide of any size, structure, or function. Typically, a protein, peptide, or polypeptide will be at least three amino acids long. A protein, peptide, or polypeptide may refer to an individual protein or a collection of proteins. One or more of the amino acids in a protein, peptide, or polypeptide may be modified, for example, by the addition of a chemical entity such as a carbohydrate group, a hydroxyl group, a phosphate group, a farnesyl group, an isofarnesyl group, a fatty acid group, a linker for conjugation, functionalization, or other modification, etc. A protein, peptide, or polypeptide may also be a single molecule or may be a multi-molecular complex. A protein, peptide, or polypeptide may be just a fragment of a naturally occurring protein or peptide. A protein, peptide, or polypeptide may be naturally occurring, recombinant, or synthetic, or any combination thereof. A protein may comprise different domains, for example, a nucleic acid binding domain and a nucleic acid cleavage domain. In some embodiments, a protein comprises a proteinaceous part, e.g., an amino acid sequence constituting a nucleic acid binding domain, and an organic compound, e.g., a compound that can act as a nucleic acid cleavage agent.

The term “randomized,” as used herein in the context of nucleic acid sequences, refers to a sequence or residue within a sequence that has been synthesized to incorporate a mixture of free nucleotides, for example, a mixture of all four nucleotides A, T, G, and C. Randomized residues are typically represented by the letter N within a nucleotide sequence. In some embodiments, a randomized sequence or residue is fully randomized, in which case the randomized residues are synthesized by adding equal amounts of the nucleotides to be incorporated (e.g., 25% T, 25% A, 25% G, and 25% C) during the synthesis step of the respective sequence residue. In some embodiments, a randomized sequence or residue is partially randomized, in which case the randomized residues are synthesized by adding non-equal amounts of the nucleotides to be incorporated (e.g., 79% T, 7% A, 7% G, and 7% C) during the synthesis step of the respective sequence residue. Partial randomization allows for the generation of sequences that are templated on a given sequence, but have incorporated mutations at a desired frequency. E.g., if a known nuclease target site is used as a synthesis template, partial randomization in which at each step the nucleotide represented at the respective residue is added to the synthesis at 79%, and the other three nucleotides are added at 7% each, will result in a mixture of partially randomized target sites being synthesized, which still represent the consensus sequence of the original target site, but which differ from the original target site at each residue with a statistical frequency of 21% for each residue so synthesized (distributed binomially). In some embodiments, a partially randomized sequence differs from the consensus sequence by more than 5%, more than 10%, more than 15%, more than 20%, more than 25%, or more than 30% on average, distributed binomially. In some embodiments, a partially randomized sequence differs from the consensus site by no more than 10%, no more than 15%, no more than 20%, no more than 25%, nor more than 30%, no more than 40%, or no more than 50% on average, distributed binomially.

The terms “small molecule” and “organic compound” are used interchangeably herein and refer to molecules, whether naturally-occurring or artificially created (e.g., via chemical synthesis) that have a relatively low molecular weight. Typically, an organic compound contains carbon. An organic compound may contain multiple carbon-carbon bonds, stereocenters, and other functional groups (e.g., amines, hydroxyl, carbonyls, or heterocyclic rings). In some embodiments, organic compounds are monomeric and have a molecular weight of less than about 1500 g/mol. In certain embodiments, the molecular weight of the small molecule is less than about 1000 g/mol or less than about 500 g/mol. In certain embodiments, the small molecule is a drug, for example, a drug that has already been deemed safe and effective for use in humans or animals by the appropriate governmental agency or regulatory body. In certain embodiments, the organic molecule is known to bind and/or cleave a nucleic acid. In some embodiments, the organic compound is an enediyne. In some embodiments, the organic compound is an antibiotic drug, for example, an anticancer antibiotic such as dynemicin, neocarzinostatin, calicheamicin, esperamicin, bleomycin, or a derivative thereof.

The term “subject,” as used herein, refers to an individual organism, for example, an individual mammal. In some embodiments, the subject is a human. In some embodiments, the subject is a non-human mammal. In some embodiments, the subject is a non-human primate. In some embodiments, the subject is a rodent. In some embodiments, the subject is a sheep, a goat, a cattle, a cat, or a dog. In some embodiments, the subject is a vertebrate, an amphibian, a reptile, a fish, an insect, a fly, or a nematode.

The terms “target nucleic acid,” and “target genome,” as used herein in the context of nucleases, refer to a nucleic acid molecule or a genome, respectively, that comprises at least one target site of a given nuclease.

The term “target site,” used herein interchangeably with the term “nuclease target site,” refers to a sequence within a nucleic acid molecule that is hound and cleaved by a nuclease. A target site may be single-stranded or double-stranded. In the context of nucleases that dimerize, for example, nucleases comprising a FokI DNA cleavage domain, a target sites typically comprises a left-half site (bound by one monomer of the nuclease), a right-half site (bound by the second monomer of the nuclease), and a spacer sequence between the half sites in which the cut is made. This structure ([left-half site]-[spacer sequence]-[right-half site]) is referred to herein as an LSR structure. In some embodiments, the left-half site and/or the right-half site is between 10-18 nucleotides long. In some embodiments, either or both half-sites are shorter or longer. In some embodiments, the left and right half sites comprise different nucleic acid sequences.

The term “Transcriptional Activator-Like Effector,” (TALE) as used herein, refers to bacterial proteins comprising a DNA binding domain, which contains a highly conserved 33-34 amino acid sequence comprising a highly variable two-amino acid motif (Repeat Variable Diresidue, RVD). The RVD motif determines binding specificity to a nucleic acid sequence, and can be engineered according to methods well known to those of skill in the art to specifically bind a desired DNA sequence (see, e.g., Miller, Jeffrey; et. al. (February 2011). “A TALE nuclease architecture for efficient genome editing”. Nature Biotechnology 29 (2): 143-8; Zhang, Feng; et. al. (February 2011). “Efficient construction of sequence-specific TAL effectors for modulating mammalian transcription”. Nature Biotechnology 29 (2): 149-53; Geiβler, R.; Scholze, H.; Hahn, S.; Streubel, J.; Bonas, U.; Behrens, S. E.; Boch, J. (2011), Shiu, Shin-Han. ed. “Transcriptional Activators of Human Genes with Programmable DNA-Specificity”. PLoS ONE 6 (5): e19509; Boch, Jens (February 2011). “TALEs of genome targeting”. Nature Biotechnology 29 (2): 135-6; Boch, Jens; et. al. (December 2009). “Breaking the Code of DNA Binding Specificity of TAL-Type III Effectors”. Science 326 (5959): 1509-12; and Moscou, Matthew J.; Adam J. Bogdanove (December 2009). “A Simple Cipher Governs DNA Recognition by TAL Effectors”. Science 326 (5959): 1501; the entire contents of each of which are incorporated herein by reference). The simple relationship between amino acid sequence and DNA recognition has allowed for the engineering of specific DNA binding domains by selecting a combination of repeat segments containing the appropriate RVDs.

The term “Transcriptional Activator-Like Element Nuclease,” (TALEN) as used herein, refers to an artificial nuclease comprising a transcriptional activator like effector DNA binding domain to a DNA cleavage domain, for example, a FokI domain. A number of modular assembly schemes for generating engineered TALE constructs have been reported (Zhang, Feng; et. al. (February 2011). “Efficient construction of sequence-specific TAL effectors for modulating mammalian transcription”. Nature Biotechnology 29 (2): 149-53; Geiβler, R.; Scholze, H.; Hahn, S.; Streubel, J.; Bonas, U.; Behrens, S. E.; Boch, J. (2011), Shiu, Shin-Han. ed. “Transcriptional Activators of Human Genes with Programmable DNA-Specificity”. PLoS ONE 6 (5): e19509; Cermak, T.; Doyle, E. L.; Christian, M.; Wang, L.; Zhang, Y.; Schmidt, C.; Bailer, J. A.; Somia, N. V. et al. (2011). “Efficient design and assembly of custom TALEN and other TAL effector-based constructs for DNA targeting”. Nucleic Acids Research; Morbitzer, R.; Elsaesser, J.; Hausner, J.; Lahaye, T. (2011). “Assembly of custom TALE-type DNA binding domains by modular cloning”. Nucleic Acids Research; Li, T.; Huang, S.; Zhao, X.; Wright, D. A.; Carpenter, S.; Spalding, M. H.; Weeks, D. P.; Yang, B. (2011). “Modularly assembled designer TAL effector nucleases for targeted gene knockout and gene replacement in eukaryotes”. Nucleic Acids Research; Weber, E.; Gruetzner, R.; Werner, S.; Engler, C.; Marillonnet, S. (2011). Bendahmane, Mohammed. ed. “Assembly of Designer TAL Effectors by Golden Gate Cloning”. PLoS ONE 6 (5): e19722; the entire contents of each of which are incorporated herein by reference).

The terms “treatment,” “treat,” and “treating,” refer to a clinical intervention aimed to reverse, alleviate, delay the onset of, or inhibit the progress of a disease or disorder, or one or more symptoms thereof, as described herein. As used herein, the terms “treatment,” “treat,” and “treating” refer to a clinical intervention aimed to reverse, alleviate, delay the onset of, or inhibit the progress of a disease or disorder, or one or more symptoms thereof, as described herein. In some embodiments, treatment may be administered after one or more symptoms have developed and/or after a disease has been diagnosed. In other embodiments, treatment may be administered in the absence of symptoms, e.g., to prevent or delay onset of a symptom or inhibit onset or progression of a disease. For example, treatment may be administered to a susceptible individual prior to the onset of symptoms (e.g., in light of a history of symptoms and/or in light of genetic or other susceptibility factors). Treatment may also be continued after symptoms have resolved, for example to prevent or delay their recurrence.

The term “zinc finger,” as used herein, refers to a small nucleic acid-binding protein structural motif characterized by a fold and the coordination of one or more zinc ions that stabilize the fold. Zinc fingers encompass a wide variety of differing protein structures (see, e.g., Klug A, Rhodes D (1987). “Zinc fingers: a novel protein fold for nucleic acid recognition”. Cold Spring Harb. Symp. Quant. Biol. 52: 473-82, the entire contents of which are incorporated herein by reference). Zinc fingers can be designed to bind a specific sequence of nucleotides, and zinc finger arrays comprising fusions of a series of zinc fingers, can be designed to bind virtually any desired target sequence. Such zinc finger arrays can form a binding domain of a protein, for example, of a nuclease, e.g., if conjugated to a nucleic acid cleavage domain. Different type of zinc finger motifs are known to those of skill in the art, including, but not limited to, Cys₂His₂, Gag knuckle, Treble clef, Zinc ribbon, Zn₂/Cys₆, and TAZ2 domain-like motifs (see, e.g., Krishna S S, Majumdar I, Grishin N V (January 2003). “Structural classification of zinc fingers: survey and summary”. Nucleic Acids Res. 31 (2): 532-50). Typically, a single zinc finger motif binds 3 or 4 nucleotides of a nucleic acid molecule. Accordingly, a zinc finger domain comprising 2 zinc finger motifs may bind 6-8 nucleotides, a zinc finger domain comprising 3 zinc finger motifs may bind 9-12 nucleotides, a zinc finger domain comprising 4 zinc finger motifs may bind 12-16 nucleotides, and so forth. Any suitable protein engineering technique can be employed to alter the DNA-binding specificity of zinc fingers and/or design novel zinc finger fusions to bind virtually any desired target sequence from 3-30 nucleotides in length (see, e.g., Pabo C O, Peisach E, Grant R A (2001). “Design and selection of novel cys2His2 Zinc finger proteins”. Annual Review of Biochemistry 70: 313-340; Jamieson A C, Miller J C, Pabo C O (2003). “Drug discovery with engineered zinc-finger proteins”. Nature Reviews Drug Discovery 2 (5): 361-368; and Liu Q, Segal D J, Ghiara J B, Barbas C F (May 1997). “Design of polydactyl zinc-finger proteins for unique addressing within complex genomes”. Proc. Natl. Acad. Sci. U.S.A. 94 (11); the entire contents of each of which are incorporated herein by reference). Fusions between engineered zinc finger arrays and protein domains that cleave a nucleic acid can be used to generate a “zinc finger nuclease.” A zinc finger nuclease typically comprises a zinc finger domain that binds a specific target site within a nucleic acid molecule, and a nucleic acid cleavage domain that cuts the nucleic acid molecule within or in proximity to the target site bound by the binding domain. Typical engineered zinc finger nucleases comprise a binding domain having between 3 and 6 individual zinc finger motifs and binding target sites ranging from 9 base pairs to 18 base pairs in length. Longer target sites are particularly attractive in situations where it is desired to bind and cleave a target site that is unique in a given genome.

The term “zinc finger nuclease,” as used herein, refers to a nuclease comprising a nucleic acid cleavage domain conjugated to a binding domain that comprises a zinc finger array. In some embodiments, the cleavage domain is the cleavage domain of the type II restriction endonuclease FokI. Zinc finger nucleases can be designed to target virtually any desired sequence in a given nucleic acid molecule for cleavage, and the possibility to the design zinc finger binding domains to bind unique sites in the context of complex genomes allows for targeted cleavage of a single genomic site in living cells, for example, to achieve a targeted genomic alteration of therapeutic value. Targeting a double-strand break to a desired genomic locus can be used to introduce frame-shift mutations into the coding sequence of a gene due to the error-prone nature of the non-homologous DNA repair pathway. Zinc finger nucleases can be generated to target a site of interest by methods well known to those of skill in the art. For example, zinc finger binding domains with a desired specificity can be designed by combining individual zinc finger motifs of known specificity. The structure of the zinc finger protein Zif268 bound to DNA has informed much of the work in this field and the concept of obtaining zinc fingers for each of the 64 possible base pair triplets and then mixing and matching these modular zinc fingers to design proteins with any desired sequence specificity has been described (Pavletich N P, Pabo C O (May 1991). “Zinc finger-DNA recognition: crystal structure of a Zif268-DNA complex at 2.1 A”. Science 252 (5007): 809-17, the entire contents of which are incorporated herein). In some embodiments, separate zinc fingers that each recognize a 3 base pair DNA sequence are combined to generate 3-, 4-, 5-, or 6-finger arrays that recognize target sites ranging from 9 base pairs to 18 base pairs in length. In some embodiments, longer arrays are contemplated. In other embodiments, 2-finger modules recognizing 6-8 nucleotides are combined to generate 4-, 6-, or 8-zinc finger arrays. In some embodiments, bacterial or phage display is employed to develop a zinc finger domain that recognizes a desired nucleic acid sequence, for example, a desired nuclease target site of 3-30 bp in length. Zinc finger nucleases, in some embodiments, comprise a zinc finger binding domain and a cleavage domain fused or otherwise conjugated to each other via a linker, for example, a polypeptide linker. The length of the linker determines the distance of the cut from the nucleic acid sequence bound by the zinc finger domain. If a shorter linker is used, the cleavage domain will cut the nucleic acid closer to the bound nucleic acid sequence, while a longer linker will result in a greater distance between the cut and the bound nucleic acid sequence. In some embodiments, the cleavage domain of a zinc finger nuclease has to dimerize in order to cut a bound nucleic acid. In some such embodiments, the dimer is a heterodimer of two monomers, each of which comprise a different zinc finger binding domain. For example, in some embodiments, the dimer may comprise one monomer comprising zinc finger domain A conjugated to a FokI cleavage domain, and one monomer comprising zinc finger domain B conjugated to a FokI cleavage domain. In this nonlimiting example, zinc finger domain A binds a nucleic acid sequence on one side of the target site, zinc finger domain B binds a nucleic acid sequence on the other side of the target site, and the dimerize FokI domain cuts the nucleic acid in between the zinc finger domain binding sites.

DETAILED DESCRIPTION OF CERTAIN EMBODIMENTS OF THE INVENTION

Introduction

Site-specific nucleases are powerful tools for the targeted modification of a genome. Some site specific nucleases can theoretically achieve a level of specificity for a target cleavage site that would allow to target a single unique site in a genome for cleavage without affecting any other genomic site. It has been reported that nuclease cleavage in living cells triggers a DNA repair mechanism that frequently results in a modification of the cleaved, repaired genomic sequence, for example, via homologous recombination. Accordingly, the targeted cleavage of a specific unique sequence within a genome opens up new avenues for gene targeting and gene modification in living cells, including cells that are hard to manipulate with conventional gene targeting methods, such as many human somatic or embryonic stem cells. Nuclease-mediated modification of disease-related sequences, e.g., the CCR-5 allele in HIV/AIDS patients, or of genes necessary for tumor neovascularization, can be used in the clinical context, and two site specific nucleases are currently in clinical trials.

One important aspect in the field of site-specific nuclease-mediated modification are off-target nuclease effects, e.g., the cleavage of genomic sequences that differ from the intended target sequence by one or more nucleotides. Undesired side effects of off-target cleavage ranges from insertion into unwanted loci during a gene targeting event to severe complications in a clinical scenario. Off target cleavage of sequences encoding essential gene functions or tumor suppressor genes by an endonuclease administered to a subject may result in disease or even death of the subject. Accordingly, it is desirable to characterize the cleavage preferences of a nuclease before using it in the laboratory or the clinic in order to determine its efficacy and safety. Further, the characterization of nuclease cleavager properties allows for the selection of the nuclease best suited for a specific task from a group of candidate nucleases, or for the selection of evolution products obtained from existing nucleases. Such a characterization of nuclease cleavage properties may also inform the de-novo design of nucleases with enhanced properties, such as enhanced specificity or efficiency.

In many scenarios where a nuclease is employed for the targeted manipulation of a nucleic acid, cleavage specificity is a crucial feature. The imperfect specificity of some engineered nuclease binding domains can lead to off-target cleavage and undesired effects both in vitro and in vivo. Current methods of evaluating site-specific nuclease specificity, including ELISA assays, microarrays, one-hybrid systems, SELEX and its variants, and Rosetta-based computational predictions, are all premised on the assumption that the binding specificity of nuclease molecules is equivalent or proportionate to their cleavage specificity.

However, the work presented here is based on the discovery that prediction of nuclease off-target binding effects constitutes an imperfect approximation of a nuclease's off-target cleavage effects that may result in undesired biological effects. This finding is consistent with the notion that the reported toxicity of some site specific DNA nucleases results from off-target DNA cleavage, rather than off-target binding alone.

The methods and reagents provided herein allow for an accurate evaluation of a given nuclease's target site specificity and provide strategies for the selection of suitable unique target sites and the design of highly specific nucleases for the targeted cleavage of a single site in the context of a complex genome. Further, methods, reagents, and strategies provided herein allow those of skill to enhance the specificity and minimize the off-target effects of any given site-specific nuclease. While of particular relevance to DNA and DNA-cleaving nucleases, the inventive concepts, methods, strategies, and reagents provided herein are not limited in this respect, but can be applied to any nucleic acid:nuclease pair.

Identifying Nuclease Target Sites Cleaved by a Site-Specific Nuclease

Some aspects of this invention provide methods and reagents to determine the nucleic acid target sites cleaved by any site-specific nuclease. In general, such methods comprise contacting a given nuclease with a library of target sites under conditions suitable for the nuclease to bind and cut a target site, and determining which target sites the nuclease actually cuts. A determination of a nuclease's target site profile based on actual cutting has the advantage over methods that rely on binding that it measures a parameter more relevant for mediating undesired off-target effects of site-specific nucleases.

In some embodiments, a method for identifying a target site of a nuclease is provided. In some embodiments, the method comprises (a) providing a nuclease that cuts a double-stranded nucleic acid target site and creates a 5′ overhang, wherein the target site comprises a [left-half site]-[spacer sequence]-[right-half site] (LSR) structure, and the nuclease cuts the target site within the spacer sequence. In some embodiments, the method comprises (b) contacting the nuclease with a library of candidate nucleic acid molecules, wherein each nucleic acid molecule comprises a concatemer of a sequence comprising a candidate nuclease target site and a constant insert sequence, under conditions suitable for the nuclease to cut a candidate nucleic acid molecule comprising a target site of the nuclease. In some embodiments, the method comprises (c) filling in the 5′ overhangs of a nucleic acid molecule that has been cut twice by the nuclease and comprises a constant insert sequence flanked by a left half-site and cut spacer sequence on one side, and a right half-site and cut spacer sequence on the other side, thereby creating blunt ends. In some embodiments, the method comprises (d) identifying the nuclease target site cut by the nuclease by determining the sequence of the left-half site, the right-half-site, and/or the spacer sequence of the nucleic acid molecule of step (c). In some embodiments, the method comprises providing a nuclease and contacting the nuclease with a library of candidate nucleic acid molecules comprising candidate target sites. In some embodiments, the candidate nucleic acid molecules are double-stranded nucleic acid molecules. In some embodiments, the candidate nucleic acid molecules are DNA molecules. In some embodiments, the nuclease dimerizes at the target site, and the target site comprises an LSR structure ([left-half site]-[spacer sequence]-[right-half site]). In some embodiments, the nuclease cuts the target site within the spacer sequence. In some embodiments, the nuclease is a nuclease that cuts a double-stranded nucleic acid target site and creates a 5′ overhang. In some embodiments, each nucleic acid molecule in the library comprises a concatemer of a sequence comprising a candidate nuclease target site and a constant insert sequence.

For example, in some embodiments, the candidate nucleic acid molecules of the library comprise the structure R₁-[(LSR)-(constant region)]_(X)-R₂, wherein R1 and R2 are, independently, nucleic acid sequences that may comprise a fragment of the [(LSR)-(constant region)] repeat unit, and X is an integer between 2 and y. In some embodiments, y is at least 10¹, at least 10², at least 10³, at least 10⁴, at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰, at least 10¹¹, at least 10¹², at least 10¹³, at least 10¹⁴, or at least 10¹⁵. In some embodiments, y is less than 10², less than 10³, less than 10⁴, less than 10⁵, less than 10⁶, less than 10⁷, less than 10⁸, less than 10⁹, less than 10¹⁰, less than 10¹¹, less than 10¹², less than 10¹³, less than 10¹⁴, or less than 10¹⁵. The constant region, in some embodiments, is of a length that allows for efficient self ligation of a single repeat unit. Suitable lengths will be apparent to those of skill in the art. For example, in some embodiments, the constant region is between 100 and 1000 base pairs long, for example, about 100 base pairs, about 200 base pairs, about 300 base pairs, about 400 base pairs, about 450 base pairs, about 500 base pairs, about 600 base pairs, about 700 base pairs, about 800 base pairs, about 900 base pairs, or about 1000 base pairs long in some embodiments, the constant region is shorter than about 100 base pairs or longer than about 1000 base pairs.

Incubation of the nuclease with the library nucleic acids will result in cleavage of those concatemers in the library that comprise target sites that can be bound and cleaved by the nuclease. If a given nuclease cleaves a specific target site with high efficiency, a concatemer comprising target sites will be cut multiple times, resulting in the generation of fragments comprising a single repeat unit. The repeat unit released from the concatemer by nuclease cleavage will be of the structure S₂R-(constant region)-LS₁, wherein S₁ and S₂ represent complementary spacer region fragments after being cut by the nuclease. Any repeat units released from library candidate molecules can then be isolated and/or the sequence of the LSR cleaved by the nuclease identified by sequencing the S₂R and LS₁ regions of released repeat units.

Any method suitable for isolation and sequencing of the repeat units can be employed to elucidate the LSR sequence cleaved by the nuclease. For example, since the length of the constant region is known, individual released repeat units can be separated based on their size from the larger uncut library nucleic acid molecules as well as from fragments of library nucleic acid molecules that comprise multiple repeat units (indicating non-efficient targeted cleavage by the nuclease). Suitable methods for separating and/or isolating nucleic acid molecules based on their size a well-known to those of skill in the art and include, for example, size fractionation methods, such as gel electrophoresis, density gradient centrifugation, and dialysis over a semi-permeable membrane with a suitable molecular cutoff value. The separated/isolated nucleic acid molecules can then be further characterized, for example, by ligating PCR and/or sequencing adapters to the cut ends and amplifying and/or sequencing the respective nucleic acids. Further, if the length of the constant region is selected to favor self-ligation of individual released repeat units, such individual released repeat units may be enriched by contacting the nuclease treated library molecules with a ligase and subsequent amplification and/or sequencing based on the circularized nature of the self-ligated individual repeat units.

In some embodiments, where a nuclease is used that generates 5′ overhangs as a result of cutting a target nucleic acid, the 5′ overhangs of the cut nucleic acid molecules are filled in. Methods for filling in 5′ overhangs are well known to those of skill in the art and include, for example, methods using DNA polymerase I Klenow fragment lacking exonuclease activity (Klenow (3′→5′ exo-)). Filling in 5′ overhangs results in the overhang-templated extension of the recessed strand, which, in turn, results in blunt ends. In the case of single repeat units released from library concatemers, the resulting structure is a blunt-ended S₂′R-(constant region)-LS₁′, with S₁′ and S₂′ comprising blunt ends. PCR and/or sequencing adapters can then be added to the ends by blunt end ligation and the respective repeat units (including S₂′R and LS₁′ regions) can be sequenced. From the sequence data, the original LSR region can be deducted. Blunting of the overhangs created during the nuclease cleavage process also allows for distinguishing between target sites that were properly cut by the respective nuclease and target sites that were non-specifically cut e.g., based on non-nuclease effects such as physical shearing. Correctly cleaved nuclease target sites can be recognized by the existence of complementary S₂′R and LS₁′ regions, which comprise a duplication of the overhang nucleotides as a result of the overhang fill in, while target sites that were not cleaved by the respective nuclease are unlikely to comprise overhang nucleotide duplications. In some embodiments, the method comprises identifying the nuclease target site cut by the nuclease by determining the sequence of the left-half site, the right-half-site, and/or the spacer sequence of a released individual repeat unit. Any suitable method for amplifying and/or sequencing can be used to identify the LSR sequence of the target site cleaved by the respective nuclease. Methods for amplifying and/or sequencing nucleic acid molecules are well known to those of skill in the art and the invention is not limited in this respect.

Some of the methods and strategies provided herein allow for the simultaneous assessment of a plurality of candidate target sites as possible cleavage targets for any given nuclease. Accordingly, the data obtained from such methods can be used to compile a list of target sites cleaved by a given nuclease, which is also referred to herein as a target site profile. If they sequencing method is used that allows for the generation of quantitative sequencing data, it is also possible to record the relative abundance of any nuclease target site detected to be cleaved by the respective nuclease. Target sites that are cleaved more efficiently by the nuclease will be detected more frequently in the sequencing step, while target sites that are not cleaved efficiently will only rarely release an individual repeat unit from a candidate concatemer, and thus, will only generate few, if any sequencing reads. Such quantitative sequencing data can be integrated into a target site profile to generate a ranked list of highly preferred and less preferred nuclease target sites.

The methods and strategies of nuclease target site profiling provided herein can be applied to any site-specific nuclease, including, for example, ZFNs, TALENs, and homing endonucleases. As described in more detail herein, nuclease specificity typically decreases with increasing nuclease concentration, and the methods described herein can be used to determine a concentration at which a given nuclease efficiently cuts its intended target site, but does not efficiently cut any off target sequences. In some embodiments, a maximum concentration of a therapeutic nuclease is determined at which the therapeutic nuclease cuts its intended nuclease target site, but does not cut more than 10, more than 5, more than 4, more than 3, more than 2, more than 1, or any additional nuclease target sites. In some embodiments, a therapeutic nuclease is administered to a subject in an amount effective to generate a final concentration equal or lower to the maximum concentration determined as described above.

Nuclease Target Site Libraries

Some embodiments of this invention provide libraries of nucleic acid molecules for nuclease target site profiling. In some embodiments such a library comprises a plurality of nucleic acid molecules, each comprising a concatemer of a candidate nuclease target site and a constant insert sequence spacer sequence. For example, in some embodiments, the candidate nucleic acid molecules of the library comprise the structure R₁-[(LSR)-(constant region)]_(X)-R₂, wherein R1 and R2 are, independently, nucleic acid sequences that may comprise a fragment of the [(LSR)-(constant region)] repeat unit, and X is an integer between 2 and y. In some embodiments, y is at least 10¹, at least 10², at least 10³, at least 10⁴, at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰, at least 10¹¹, at least 10¹², at least 10¹³, at least 10¹⁴, or at least 10¹⁵. In some embodiments, y is less than 10², less than 10³, less than 10⁴, less than 10⁵, less than 10⁶, less than 10⁷, less than 10⁸, less than 10⁹, less than 10¹⁰, less than 10¹¹, less than 10¹², less than 10¹³, less than 10¹⁴, or less than 10¹⁵. The constant region, in some embodiments, is of a length that allows for efficient self ligation of a single repeat unit. In some embodiments, the constant region is of a length that allows for efficient separation of single repeat units from fragments comprising two or more repeat units. In some embodiments, the concentration is over length allows for efficient sequencing of a complete repeat unit in one sequencing read. Suitable lengths will be apparent to those of skill in the art. For example, in some embodiments, the constant region is between 100 and 1000 base pairs long, for example, about 100 base pairs, about 200 base pairs, about 300 base pairs, about 400 base pairs, about 450 base pairs, about 500 base pairs, about 600 base pairs, about 700 base pairs, about 800 base pairs, about 900 base pairs, or about 1000 base pairs long in some embodiments, the constant region is shorter than about 100 base pairs or longer than about 1000 base pairs.

An LSR site typically comprises a [left-half site]-[spacer sequence]-[right-half site] structure. The lengths of the half-size and the spacer sequence will depend on the specific nuclease to be evaluated. In general, the half-sites will be 6-30 nucleotides long, and preferably 10-18 nucleotides long. For example, each half site individually may be 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, or 30 nucleotides long. In some embodiments, an LSR site may be longer than 30 nucleotides. In some embodiments, the left half site and the right half site of an LSR are of the same length. In some embodiments, the left half site and the right half site of an LSR are of different lengths. In some embodiments, the left half site and the right half site of an LSR are of different sequences. In some embodiments, a library is provided that comprises candidate nucleic acids which comprise LSRs that can be cleaved by a FokI cleavage domain, a Zinc Finger Nuclease (ZFN), a Transcription Activator-Like Effector Nuclease (TALEN), a homing endonuclease, an organic compound nuclease, an enediyne, an antibiotic nuclease, dynemicin, neocarzinostatin, calicheamicin, esperamicin, and/or bleomycin.

In some embodiments, a library of candidate nucleic acid molecules is provided that comprises at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰, at least 10¹¹, or at least 10¹² different candidate nuclease target sites. In some embodiments, the candidate nucleic acid molecules of the library are concatemers produced from a secularized templates by rolling cycle amplification. In some embodiments, the library comprises nucleic acid molecules, e.g., concatemers, of a molecular weight of at least 5 kDa, at least 6 kDa, at least 7 kDa, at least 8 kDa, at least 9 kDa, at least 10 kDa, at least 12 kDa, or at least 15 kDa. in some embodiments, the molecular weight of the nucleic acid molecules within the library may be larger than 15 kDa. In some embodiments, the library comprises nucleic acid molecules within a specific size range, for example, within a range of 5-7 kDa, 5-10 kDa, 8-12 kDa, 10-15 kDa, or 12-15 kDa, or 5-10 kDa or any possible subrange. While some methods suitable for generating nucleic acid concatemers according to some aspects of this invention result in the generation of nucleic acid molecules of greatly different molecular weights, such mixtures of nucleic acid molecules may be size fractionated to obtain a desired size distribution. Suitable methods for enriching nucleic acid molecules of a desired size or excluding nucleic acid molecules of a desired size are well known to those of skill in the art and the invention is not limited in this respect.

In some embodiments, a library is provided comprising candidate nucleic acid molecules that comprise target sites with a partially randomized left-half site, a partially randomized right-half site, and/or a partially randomized spacer sequence.

In some embodiments, the library is provided comprising candidate nucleic acid molecules that comprise target sites with a partially randomized left half site, a fully randomized spacer sequence, and a partially randomized right half site. In some embodiments, partially randomized sites differ from the consensus site by more than 5%, more than 10%, more than 15%, more than 20%, more than 25%, or more than 30% on average, distributed binomially. In some embodiments, partially randomized sites differ from the consensus site by no more than 10%, no more than 15%, no more than 20%, no more than 25%, nor more than 30%, no more than 40%, or no more than 50% on average, distributed binomially. For example, in some embodiments partially randomized sites differ from the consensus site by more than 5%, but by no more than 10%; by more than 10%, but by no more than 20%; by more than 20%, but by no more than 25%; by more than 5%, but by no more than 20%, and so on. Using partially randomized nuclease target sites in the library is useful to increase the concentration of library members comprising target sites that are closely related to the consensus site, for example, that differ from the consensus sites in only one, only two, only three, only four, or only five residues. The rationale behind this is that a given nuclease, for example a given ZFN, is likely to cut its intended target site and any closely related target sites, but unlikely to cut a target sites that is vastly different from or completely unrelated to the intended target site. Accordingly, using a library comprising partially randomized target sites can be more efficient than using libraries comprising fully randomized target sites without compromising the sensitivity in detecting any off target cleavage events for any given nuclease. Thus, the use of partially randomized libraries significantly reduces the cost and effort required to produce a library having a high likelihood of covering virtually all off target sites of a given nuclease. In some embodiments however it may be desirable to use a fully randomized library of target sites, for example, in embodiments, where the specificity of a given nuclease is to be evaluated in the context of any possible site in a given genome. Selection and Design of Site-Specific Nucleases

Some aspects of this invention provide methods and strategies for selecting and designing site-specific nucleases that allow the targeted cleavage of a single, unique sites in the context of a complex genome. In some embodiments, a method is provided that comprises providing a plurality of candidate nucleases that are designed or known to cut the same consensus sequence; profiling the target sites actually cleaved by each candidate nuclease, thus detecting any cleaved off-target sites (target sites that differ from the consensus target site); and selecting a candidate nuclease based on the off-target site(s) so identified. In some embodiments, this method is used to select the most specific nuclease from a group of candidate nucleases, for example, the nuclease that cleaves the consensus target site with the highest specificity, the nuclease that cleaves the lowest number of off-target sites, the nuclease that cleaves the lowest number of off-target sites in the context of a target genome, or a nuclease that does not cleave any target site other than the consensus target site. In some embodiments, this method is used to select a nuclease that does not cleave any off-target site in the context of the genome of a subject at concentration that is equal to or higher than a therapeutically effective concentration of the nuclease.

The methods and reagents provided herein can be used, for example, to evaluate a plurality of different nucleases targeting the same intended targets site, for example, a plurality of variations of a given site-specific nuclease, for example a given zinc finger nuclease. Accordingly, such methods may be used as the selection step in evolving or designing a novel site-specific nucleases with improved specificity.

Identifying Unique Nuclease Target Sites within a Genome

Some embodiments of this invention provide a method for selecting a nuclease target site within a genome. As described in more detail elsewhere herein, it was surprisingly discovered that off target sites cleaved by a given nuclease are typically highly similar to the consensus target site, e.g., differing from the consensus target site in only one, only two, only three, only four, or only five nucleotide residues. Based on this discovery, a nuclease target sites within the genome can be selected to increase the likelihood of a nuclease targeting this site not cleaving any off target sites within the genome. For example, in some embodiments, a method is provided that comprises identifying a candidate nuclease target site; and comparing the candidate nuclease target site to other sequences within the genome. Methods for comparing candidate nuclease target sites to other sequences within the genome are well known to those of skill in the art and include for example sequence alignment methods, for example, using a sequence alignment software or algorithm such as BLAST on a general purpose computer. A suitable unique nuclease target site can then be selected based on the results of the sequence comparison. In some embodiments, if the candidate nuclease target site differs from any other sequence within the genome by at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9, or at least 10 nucleotides, the nuclease target site is selected as a unique site within the genome, whereas if the site does not fulfill this criteria, the site may be discarded. In some embodiments, once a site is selected based on the sequence comparison, as outlined above, a site-specific nuclease targeting the selected site is designed. For example, a zinc finger nuclease may be designed to target any selected nuclease target site by constructing a zinc finger array binding the target site, and conjugating the zinc finger array to a DNA cleavage domain. In embodiments where the DNA cleavage domain needs to dimerize in order to cleave DNA, to zinc finger arrays will be designed, each binding a half site of the nuclease target site, and each conjugated to a cleavage domain. In some embodiments, nuclease designing and/or generating is done by recombinant technology. Suitable recombinant technologies are well known to those of skill in the art, and the invention is not limited in this respect.

In some embodiments, a site-specific nuclease designed or generated according to aspects of this invention is isolated and/or purified. The methods and strategies for designing site-specific nucleases according to aspects of this invention can be applied to design or generate any site-specific nuclease, including, but not limited to Zinc Finger Nucleases, Transcription Activator-Like Effector Nucleases (TALENs), homing endonucleases, organic compound nucleases, enediyne nucleases, antibiotic nucleases, and dynemicin, neocarzinostatin, calicheamicin, esperamicin, bleomycin, or a derivative thereof variants or derivatives.

Site-Specific Nucleases

Some aspects of this invention provide isolated site-specific nucleases with enhanced specificity that are designed using the methods and strategies described herein. Some embodiments, of this invention provide nucleic acids encoding such nucleases. Some embodiments of this invention provide expression constructs comprising such encoding nucleic acids. For example, in some embodiments an isolated nuclease is provided that has been engineered to cleave a desired target site within a genome, and has been evaluated according to a method provided herein to cut less than 1, less than 2, less than 3, less than 4, less than 5, less than 6, less than 7, less than 8, less than 9 or less than 10 off-target sites at a concentration effective for the nuclease to cut its intended target site. In some embodiments an isolated nuclease is provided that has been engineered to cleave a desired unique target site that has been selected to differ from any other site within a genome by at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9, or at least 10 nucleotide residues. In some embodiments, the isolated nuclease is a Zinc Finger Nuclease (ZFN) or a Transcription Activator-Like Effector Nuclease (TALEN), a homing endonuclease, or is or comprises an organic compound nuclease, an enediyne, an antibiotic nuclease, dynemicin, neocarzinostatin, calicheamicin, esperamicin, bleomycin, or a derivative thereof. In some embodiments, the isolated nuclease cleaves a consensus target site within an allele that is associated with a disease or disorder. In some embodiments, the isolated nuclease cleaves a consensus target site the cleavage of which results in treatment or prevention of a disease or disorder. In some embodiments, the disease is HIV/AIDS, or a proliferative disease. In some embodiments, the allele is a CCR5 (for treating HIV/AIDS) or a VEGFA allele (for treating a proliferative disease).

In some embodiments, the isolated nuclease is provided as part of a pharmaceutical composition. For example, some embodiments provide pharmaceutical compositions comprising a nuclease as provided herein, or a nucleic acid encoding such a nuclease, and a pharmaceutically acceptable excipient. Pharmaceutical compositions may optionally comprise one or more additional therapeutically active substances.

In some embodiments, compositions provided herein are administered to a subject, for example, to a human subject, in order to effect a targeted genomic modification within the subject. In some embodiments, cells are obtained from the subject and contacted with a nuclease or a nuclease-encoding nucleic acid ex vivo, and re-administered to the subject after the desired genomic modification has been effected or detected in the cells. Although the descriptions of pharmaceutical compositions provided herein are principally directed to pharmaceutical compositions which are suitable for administration to humans, it will be understood by the skilled artisan that such compositions are generally suitable for administration to animals of all sorts. Modification of pharmaceutical compositions suitable for administration to humans in order to render the compositions suitable for administration to various animals is well understood, and the ordinarily skilled veterinary pharmacologist can design and/or perform such modification with merely ordinary, if any, experimentation. Subjects to which administration of the pharmaceutical compositions is contemplated include, but are not limited to, humans and/or other primates; mammals, including commercially relevant mammals such as cattle, pigs, horses, sheep, cats, dogs, mice, and/or rats; and/or birds, including commercially relevant birds such as chickens, ducks, geese, and/or turkeys.

Formulations of the pharmaceutical compositions described herein may be prepared by any method known or hereafter developed in the art of pharmacology. In general, such preparatory methods include the step of bringing the active ingredient into association with an excipient and/or one or more other accessory ingredients, and then, if necessary and/or desirable, shaping and/or packaging the product into a desired single- or multi-dose unit.

Pharmaceutical formulations may additionally comprise a pharmaceutically acceptable excipient, which, as used herein, includes any and all solvents, dispersion media, diluents, or other liquid vehicles, dispersion or suspension aids, surface active agents, isotonic agents, thickening or emulsifying agents, preservatives, solid hinders, lubricants and the like, as suited to the particular dosage form desired. Remington's The Science and Practice of Pharmacy, 21^(st) Edition, A. R. Gennaro (Lippincott, Williams & Wilkins, Baltimore, Md., 2006; incorporated herein by reference) discloses various excipients used in formulating pharmaceutical compositions and known techniques for the preparation thereof. Except insofar as any conventional excipient medium is incompatible with a substance or its derivatives, such as by producing any undesirable biological effect or otherwise interacting in a deleterious manner with any other component(s) of the pharmaceutical composition, its use is contemplated to be within the scope of this invention.

The function and advantage of these and other embodiments of the present invention will be more fully understood from the Examples below. The following Examples are intended to illustrate the benefits of the present invention and to describe particular embodiments, hut are not intended to exemplify the full scope of the invention. Accordingly, it will be understood that the Examples are not meant to limit the scope of the invention.

EXAMPLES Example 1—Zinc Finger Nucleases

Introduction

Zinc finger nucleases (ZFNs) are enzymes engineered to recognize and cleave desired target DNA sequences. A ZFN monomer consists of a zinc finger DNA-binding domain fused with a non-specific FokI restriction endonuclease cleavage domain¹. Since the FokI nuclease domain must dimerize and bridge two DNA half-sites to cleave DNA², ZFNs are designed to recognize two unique sequences flanking a spacer sequence of variable length and to cleave only when bound as a dimer to DNA. ZFNs have been used for genome engineering in a variety of organisms including mammals³⁻⁹ by stimulating either non-homologous end joining or homologous recombination. In addition to providing powerful research tools, ZFNs also have potential as gene therapy agents. Indeed, two ZFNs have recently entered clinical trials: one as part of an anti-HIV therapeutic approach (NCT00842634, NCT01044654, NCT01252641) and the other to modify cells used as anti-cancer therapeutics (NCT01082926).

DNA cleavage specificity is a crucial feature of ZFNs. The imperfect specificity of some engineered zinc fingers domains has been linked to cellular toxicity¹⁰ and therefore determining the specificities of ZFNs is of significant interest. ELISA assays¹¹, microarrays¹², a bacterial one-hybrid system¹³, SELEX and its variants¹⁴⁻¹⁶, and Rosetta-based computational predictions¹⁷ have all been used to characterize the DNA-binding specificity of monomeric zinc finger domains in isolation. However, the toxicity of ZFNs is believed to result from DNA cleavage, rather than binding alone^(18,19). As a result, information about the specificity of zinc finger nucleases to date has been based on the unproven assumptions that (i) dimeric zinc finger nucleases cleave DNA with the same sequence specificity with which isolated monomeric zinc finger domains bind DNA; and (ii) the binding of one zinc finger domain does not influence the binding of the other zinc finger domain in a given ZFN. The DNA-binding specificities of monomeric zinc finger domains have been used to predict potential off-target cleavage sites of dimeric ZFNs in genomes^(6,20), but to our knowledge no study to date has reported a method for determining the broad DNA cleavage specificity of active, dimeric zinc finger nucleases.

In this work we present an in vitro selection method to broadly examine the DNA cleavage specificity of active ZFNs. Our selection was coupled with high-throughput DNA sequencing technology to evaluate two obligate heterodimeric ZFNs, CCR5-224⁶, currently in clinical trials (NCT00842634, NCT01044654, NCT01252641), and VF2468⁴, that targets the human VEGF-A promoter, for their abilities to cleave each of 10¹¹ potential target sites. We identified 37 sites present in the human genome that can be cleaved in vitro by CCR5-224, 2,652 sites in the human genome that can be cleaved in vitro by VF2468, and hundreds of thousands of in vitro cleavable sites for both ZFNs that are not present in the human genome. To demonstrate that sites identified by our in vitro selection can also be cleaved by ZFNs in cells, we examined 34 or 90 sites for evidence of ZFN-induced mutagenesis in cultured human K562 cells expressing the CCR5-224 or VF2468 ZFNs, respectively. Ten of the CCR5-224 sites and 32 of the VF2468 sites we tested show DNA sequence changes consistent with ZFN-mediated cleavage in human cells, although we anticipate that cleavage is likely to be dependent on cell type and ZFN concentration. One CCR5-224 off-target site lies in a promoter of the malignancy-associated BTBD10 gene.

Our results, which could not have been obtained by determining binding specificities of monomeric zinc finger domains alone, indicate that excess DNA-binding energy results in increased off-target ZFN cleavage activity and suggest that ZFN specificity can be enhanced by designing ZFNs with decreased binding affinity, by lowering ZFN expression levels, and by choosing target sites that differ by at least three base pairs from their closest sequence relatives in the genome.

Results

In Vitro Selection for ZFN-Mediated DNA Cleavage

Libraries of potential cleavage sites were prepared as double-stranded DNA using synthetic primers and PCR (FIG. 5). Each partially randomized position in the primer was synthesized by incorporating a mixture containing 79% wild-type phosphoramidite and 21% of an equimolar mixture of all three other phosphoramidites. Library sequences therefore differed from canonical ZFN cleavage sites by 21% on average, distributed binomially. We used a blunt ligation strategy to create a 10¹²-member minicircle library. Using rolling-circle amplification, >10¹¹ members of this library were both amplified and concatenated into high molecular weight (>12 kb) DNA molecules. In theory, this library covers with at least 10-fold excess all DNA sequences that are seven or fewer mutations from the wild-type target sequences.

We incubated the CCR5-224 or VF2468 DNA cleavage site library at a total cleavage site concentration of 14 nM with two-fold dilutions, ranging from 0.5 nM to 4 nM, of crude in vitro-translated CCR5-224 or VF2468, respectively (FIG. 6). Following digestion, we subjected the resulting DNA molecules (FIG. 7) to in vitro selection for DNA cleavage and subsequent paired-end high-throughput DNA sequencing. Briefly, three selection steps (FIG. 1) enabled the separation of sequences that were cleaved from those that were not. First, only sites that had been cleaved contained 5′ phosphates, which are necessary for the ligation of adapters required for sequencing. Second, after PCR, a gel purification step enriched the smaller, cleaved library members. Finally, a computational filter applied after sequencing only counted sequences that have filled-in, complementary 5′ overhangs on both ends, the hallmark for cleavage of a target site concatemer (Table 2 and Protocols 1-9). We prepared pre-selection library sequences for sequencing by cleaving the library at a PvuI restriction endonuclease recognition site adjacent to the library sequence and subjecting the digestion products to the same protocol as the ZFN-digested library sequences. High-throughput sequencing confirmed that the rolling-circle-amplified, pre-selection library contained the expected distribution of mutations (FIG. 8).

Design of an In Vitro Selection for ZFN-Mediated DNA Cleavage.

To characterize comprehensively the DNA cleavage specificity of active ZFNs, we first generated a large library of potential DNA substrates that can be selected for DNA cleavage in one step without requiring iterative enrichment steps that could amplify noise and introduce bias. We designed the substrate library such that each molecule in the library is a concatemer of one of >10¹¹ potential substrate sequences (FIG. 5). Incubation with ZFN results in some molecules that are uncut, some that have been cut once, and some that have been cut at least twice. Those molecules that have been cleaved at least twice have ends consisting of each half of the cleaved DNA sequence (FIG. 1). Cut library members are enriched relative to uncut library members in three ways (FIG. 1). First, sequences that have been cleaved twice have two complementary 5′ overhangs, which can be identified computationally following DNA sequencing as hallmarks of bona fide cleavage products. Second, since ZFN-mediated cleavage reveals 5′ phosphates that are not present in the pre-selection library, only DNA that has undergone cleavage is amenable to sequencing adapter ligation. Third, after PCR using primers complementary to the sequencing adapters, a gel purification step ensures that all sequenced material is of a length consistent with library members that have been cleaved at two adjacent sites. This gel-purified material is subjected to high-throughput DNA sequencing using the Illumina method (Bentley, D. R. et al. Accurate whole human genome sequencing using reversible terminator chemistry. Nature 456, 53-9 (2008)). Ideally, the library used in a ZFN cleavage selection would consist of every possible DNA sequence of the length recognized by the ZFN. Only one out of every 105 members of such a library, however, would contain a sequence that was within seven mutations of a 24-base pair recognition sequence. Since off-target recognition sequences most likely resemble target recognition sites, we used instead a biased library that ensures >10-fold coverage of all half-site sequences that differ from the wild-type recognition sequences by up to seven mutations. Library members consist of a fully randomized base pair adjacent to the 5′ end of the recognition site, two partially randomized half sites flanking a 4-, 5-, 6-, or 7-bp fully randomized spacer, and another fully randomized base pair adjacent to the 3′ end of the recognition site. A fully randomized five-base pair tag follows each library member. This tag, along with the randomized flanking base pairs and the randomized spacer sequence, was used as a unique identifier “key” for each library member. If this unique key was associated with more than one sequence read containing identical library members, these duplicate sequencing reads likely arose during PCR amplification and were therefore treated as one data point.

Analysis of CCR5-224 and VF2468 ZFNs Using the DNA Cleavage Selection.

Each member of a sequence pair consisted of a fragment of the spacer, an entire half-site, an adjacent nucleotide, and constant sequence. One end of the spacer was generally found in one sequence and the other end in its corresponding paired sequence, with the overhang sequence present in both paired sequence reads because overhangs were blunted by extension prior to ligation of adapters. The spacer sequences were reconstructed by first identifying the shared overhang sequence and then any nucleotides present between the overhang sequence and the half-site sequence. Only sequences containing no ambiguous nucleotides and overhangs of at least 4 nucleotides were analyzed. Overall, this computational screen for unique sequences that originated from two cleavage events on identical library members yielded 2.0 million total reads of cleaved library members (Table 2). There are far fewer analyzed sequences for the 0.5 nM, 1 nM, and 2 nM CCR5-224 and VF2468 selections compared to the 4 nM selections due to the presence of a large number of sequence repeats, identified through the use of the unique identifier key described above. The high abundance of repeated sequences in the 0.5 nM, 1 nM, and 2 nM selections indicate that the number of sequencing reads obtained in those selections, before repeat sequences were removed, was larger than the number of individual DNA sequences that survived all experimental selection steps. We estimated the error rate of sequencing to be 0.086% per nucleotide by analysis of a constant nucleotide in all paired reads. Using this error rate, we estimate that 98% of the post-selection ZFN target site sequences contain no errors.

Off-Target Cleavage is Dependent on ZFN Concentration

As expected, only a subset of library members was cleaved by each enzyme. The pre-selection libraries for CCR5-224 and VF2468 contained means of 4.56 and 3.45 mutations per complete target site (two half-sites), respectively, while post-selection libraries exposed to the highest concentrations of ZFN used (4 nM CCR5-224 and 4 nM VF2468) had means of 2.79 and 1.53 mutations per target site, respectively (FIG. 8). As ZFN concentration decreased, both ZFNs exhibited less tolerance for off-target sequences. At the lowest concentrations (0.5 nM CCR5-224 and 0.5 nM VF2468), cleaved sites contained an average of 1.84 and 1.10 mutations, respectively. We placed a small subset of the identified sites in a new DNA context and incubated in vitro with 2 nM CCR5-224 or 1 nM VF2468 for 4 hours at 37° C. (FIG. 9). We observed cleavage for all tested sites and those sites emerging from the more stringent (low ZFN concentration) selections were cleaved more efficiently than those from the less stringent selections. Notably, all of the tested sequences contain several mutations, yet some were cleaved in vitro more efficiently than the designed target.

The DNA-cleavage specificity profile of the dimeric CCR5-224 ZFN (FIG. 2a and FIG. 10a,b ) was notably different than the DNA-binding specificity profiles of the CCR5-224 monomers previously determined by SELEX⁶. For example, some positions, such as (+)A5 and (+)T9, exhibited tolerance for off-target base pairs in our cleavage selection that were not predicted by the SELEX study. VF2468, which had not been previously characterized with respect to either DNA-binding or DNA-cleavage specificity, revealed two positions, (−)C5 and (+)A9, that exhibited limited sequence preference, suggesting that they were poorly recognized by the ZFNs (FIG. 2b and FIG. 10c,d ).

Compensation Between Half-Sites Affects DNA Recognition

Our results reveal that ZFN substrates with mutations in one half-site are more likely to have additional mutations in nearby positions in the same half-site compared to the pre-selection library and less likely to have additional mutations in the other half-site. While this effect was found to be largest when the most strongly recognized base pairs were mutated (FIG. 11), we observed this compensatory phenomenon for all specified half-site positions for both the CCR5 and VEGF-targeting ZFNs (FIG. 3 and FIG. 12). For a minority of nucleotides in cleaved sites, such as VF2468 target site positions (+)G1, (−)G1, (−)A2, and (−)C3, mutation led to decreased tolerance of mutations in base pairs in the other half-site and also a slight decrease, rather than an increase, in mutational tolerance in the same half-site. When two of these mutations, (+)G1 and (−)G1, were enforced at the same time, mutational tolerance at all other positions decreased (FIG. 13). Collectively, these results show that tolerance of mutations at one half-site is influenced by DNA recognition at the other half-site.

This compensation model for ZFN site recognition applies not only to non-ideal half-sites, but also to spacers with non-ideal lengths. In general, the ZFNs cleaved at characteristic locations within the spacers (FIG. 14), and five- and six-base pair spacers were preferred over four- and seven-base pair spacers (FIGS. 15 and 16). However, cleaved sites with five- or six-base pair spacers showed greater sequence tolerance at the flanking half-sites than sites with four- or seven-base pair spacers (FIG. 17). Therefore, spacer imperfections, similar to half-site mutations, lead to more stringent in vitro recognition of other regions of the DNA substrate.

ZFNs can Cleave Many Sequences with Up to Three Mutations

We calculated enrichment factors for all sequences containing three or fewer mutations by dividing each sequence's frequency of occurrence in the post-selection libraries by its frequency of occurrence in the pre-selection libraries. Among sequences enriched by cleavage (enrichment factor >1), CCR5-224 was capable of cleaving all unique single-mutant sequences, 93% of all unique double-mutant sequences, and half of all possible triple-mutant sequences (FIG. 4a and Table 3a) at the highest enzyme concentration used. VF2468 was capable of cleaving 98% of all unique single-mutant sequences, half of all unique double-mutant sequences, and 17% of all triple-mutant sequences (FIG. 4b and Table 3b).

Since our approach assays active ZFN dimers, it reveals the complete sequences of ZFN sites that can be cleaved. Ignoring the sequence of the spacer, the selection revealed 37 sites in the human genome with five- or six-base pair spacers that can be cleaved in vitro by CCR5-224 (Table 1 and Table 4), and 2,652 sites in the human genome that can be cleaved by VF2468 (VF2468 Data). Among the genomic sites that were cleaved in vitro by VF2468, 1,428 sites had three or fewer mutations relative to the canonical target site (excluding the spacer sequence). Despite greater discrimination against single-, double-, and triple-mutant sequences by VF2468 compared to CCR5-224 (FIG. 4 and Table 3), the larger number of in vitro-cleavable VF2468 sites reflects the difference in the number of sites in the human genome that are three or fewer mutations away from the VF2468 target site (3,450 sites) versus those that are three or fewer mutations away from the CCR5-224 target site (eight sites) (Table 5).

Identified Sites are Cleaved by ZFNs in Human Cells

We tested whether CCR5-224 could cleave at sites identified by our selections in human cells by expressing CCR5-224 in K562 cells and examining 34 potential target sites within the human genome for evidence of ZFN-induced mutations using PCR and high-throughput DNA sequencing. We defined sites with evidence of ZFN-mediated cleavage as those with insertion or deletion mutations (indels) characteristic of non-homologous end joining (NHEJ) repair (Table 6) that were significantly enriched (P<0.05) in cells expressing active CCR5-224 compared to control cells containing an empty vector. We obtained approximately 100,000 sequences or more for each site analyzed, which enabled the detection of sites that were significantly modified at frequencies of approximately 1 in 10,000. Our analysis identified ten such sites: the intended target sequence in CCR5, a previously identified sequence in CCR2, and eight other off-target sequences (Tables 1, 4, and 6), one of which lies within the promoter of the BTBD10 gene. The eight newly identified off-target sites are modified at frequencies ranging from 1 in 300 to 1 in 5,300. We also expressed VF2468 in cultured K562 cells and performed the above analysis for 90 of the most highly cleaved sites identified by in vitro selection. Out of the 90 VF2468 sites analyzed, 32 showed indels consistent with ZFN-mediated targeting in K562 cells (Table 7). We were unable to obtain site-specific PCR amplification products for three CCR5-224 sites and seven VF2468 sites and therefore could not analyze the occurrence of NHEJ at those loci. Taken together, these observations indicate that off-target sequences identified through the in vitro selection method include many DNA sequences that can be cleaved by ZFNs in human cells.

Discussion

The method presented here identified hundreds of thousands of sequences that can be cleaved by two active, dimeric ZFNs, including many that are present and can be cut in the genome of human cells. One newly identified cleavage site for the CCR5-224 ZFN is within the promoter of the BTBD10 gene. When downregulated, BTBD10 has been associated with malignancy²¹ and with pancreatic beta cell apoptosis²². When upregulated, BTBD10 has been shown to enhance neuronal cell growth²³ and pancreatic beta cell proliferation through phosphorylation of Akt family proteins^(22,23). This potentially important off-target cleavage site as well as seven others we observed in cells were not identified in a recent study⁶ that used in vitro monomer-binding data to predict potential CCR5-224 substrates.

We have previously shown that ZFNs that can cleave at sites in one cell line may not necessarily function in a different cell line⁴, most likely due to local differences in chromatin structure. Therefore, it is likely that a different subset of the in vitro-cleavable off-target sites would be modified by CCR5-224 or VF2468 when expressed in different cell lines. Purely cellular studies of endonuclease specificity, such as a recent study of homing endonuclease off-target cleavage²⁴, may likewise be influenced by cell line choice. While our in vitro method does not account for some features of cellular DNA, it provides general, cell type-independent information about endonuclease specificity and off-target sites that can inform subsequent studies performed in cell types of interest. In addition, while our pre-selection library oversamples with at least 10-fold coverage all sequences within seven mutations of the intended ZFN target sites, the number of sequence reads obtained per selection (approximately one million) is likely insufficient to cover all cleaved sequences present in the post-selection libraries. It is therefore possible that additional off-target cleavage sites for CCR5-224 and VF2468 could be identified in the human genome as sequencing capabilities continue to improve.

Although both ZFNs we analyzed were engineered to a unique sequence in the human genome, both cleave a significant number of off-target sites in cells. This finding is particularly surprising for the four-finger CCR5-224 pair given that its theoretical specificity is 4,096-fold better than that of the three-finger VF2468 pair (CCR5-224 should recognize a 24-base pair site that is six base pairs longer than the 18-base pair VF2468 site). Examination of the CCR5-224 and VF2468 cleavage profiles (FIG. 2) and mutational tolerances of sequences with three or fewer mutations (FIG. 4) suggests different strategies may be required to engineer variants of these ZFNs with reduced off-target cleavage activities. The four-finger CCR5-224 ZFN showed a more diffuse range of positions with relaxed specificity and a higher tolerance of mutant sequences with three or fewer mutations than the three-finger VF2468 ZFN. For VF2468, re-optimization of only a subset of fingers may enable a substantial reduction in undesired cleavage events. For CCR5-224, in contrast, a more extensive re-optimization of many or all fingers may be required to eliminate off-target cleavage events.

We note that not all four- and three-finger ZFNs will necessarily be as specific as the two ZFNs tested in this study. Both CCR5-224 and VF2468 were engineered using methods designed to optimize the binding activity of the ZFNs. Previous work has shown that for both three-finger and four-finger ZFNs, the specific methodology used to engineer the ZFN pair can have a tremendous impact on the quality and specificity of nucleases^(7,13,25,26).

Our findings have significant implications for the design and application of ZFNs with increased specificity. Half or more of all potential substrates with one or two site mutations could be cleaved by ZFNs, suggesting that binding affinity between ZFN and DNA substrate is sufficiently high for cleavage to occur even with suboptimal molecular interactions at mutant positions. We also observed that ZFNs presented with sites that have mutations in one half-site exhibited higher mutational tolerance at other positions within the mutated half-site and lower tolerance at positions in the other half-site. These results collectively suggest that in order to meet a minimum affinity threshold for cleavage, a shortage of binding energy from a half-site harboring an off-target base pair must be energetically compensated by excess zinc finger:DNA binding energy in the other half-site, which demands increased sequence recognition stringency at the non-mutated half-site (Fig. S18). Conversely, the relaxed stringency at other positions in mutated half-sites can be explained by the decreased contribution of that mutant half-site to overall ZFN binding energy. This hypothesis is supported by a recent study showing that reducing the number of zinc fingers in a ZFN can actually increase, rather than decrease, activity²⁷.

This model also explains our observation that sites with suboptimal spacer lengths, which presumably were bound less favorably by ZFNs, were recognized with higher stringency than sites with optimal spacer lengths. In vitro spacer preferences do not necessarily reflect spacer preferences in cells;^(28,29) however, our results suggest that the dimeric FokI cleavage domain can influence ZFN target-site recognition. Consistent with this model, Wolfe and co-workers recently observed differences in the frequency of off-target events in zebrafish of two ZFNs with identical zinc-finger domains but different FokI domain variants.²⁰

Collectively, our findings suggest that (i) ZFN specificity can be increased by avoiding the design of ZFNs with excess DNA binding energy; (ii) off-target cleavage can be minimized by designing ZFNs to target sites that do not have relatives in the genome within three mutations; and (iii) ZFNs should be used at the lowest concentrations necessary to cleave the target sequence to the desired extent. While this study focused on ZFNs, our method should be applicable to all sequence-specific endonucleases that cleave DNA in vitro, including engineered horning endonucleases and engineered transcription activator-like effector (TALE) nucleases. This approach can provide important information when choosing target sites in genomes for sequence-specific endonucleases, and when engineering these enzymes, especially for therapeutic applications.

Methods

Oligonucleotides and Sequences.

All oligonucleotides were purchased from Integrated DNA Technologies or Invitrogen and are listed in Table 8. Primers with degenerate positions were synthesized by Integrated DNA Technologies using hand-mixed phosphoramidites containing 79% of the indicated base and 7% of each of the other standard DNA bases.

Sequences of ZFNs Used in this Study.

DNA and protein sequences are shown for the ZFNs used in this study. The T7 promoter is underlined, and the start codon is in bold.

CCR5-224 (+) DNA sequence (SEQ ID NO: 119): TAATACGACTCACTATAGGGAGACCCAAGCTGGCTAGCCACCATGGACTACAAAGACCATGACGGTGATTATAAA GATCATGACATCGATTACAAGGATGACGATGACAAGATGGCCCCCAAGAAGAAGAGGAAGGTGGGCATTCACGGG GTACCCGCCGCTATGGCTGAGAGGCCCTTCCAGTGTCGAATCTGCATGCGTAACTTCAGTGATCGCTCTAACCTG AGTCGGCACATCCGCACCCACACAGGCGAGAAGCCTTTTGCCTGTGACATTTGTGGGAGGAAGTTTGCCATCTCC TCCAACCTGAACTCCCATACCAAGATACACACGGGATCTCAGAAGCCCTTCCAGTGTCGAATCTGCATGCGTAAC TTCAGTCGCTCCGACAACCTGGCCCGCCACATCCGCACCCACACAGGCGAGAAGCCTTTTGCCTGTGACATTTGT GGGAGGAAATTTGCCACCTCCGGCAACCTGACCCGCCATACCAAGATACACCTGCGGGGATCCCAACTAGTCAAA AGTGAACTGGAGGAGAAGAAATCTGAACTTCGTCATAAATTGAAATATGTGCCTCATGAATATATTGAATTAATT GAAATTGCCAGAAATTCCACTCAGGATAGAATTCTTGAAATGAAGGTAATGGAATTTTTTATGAAAGTTTATGGA TATAGAGGTAAACATTTGGGTGGATCAAGGAAACCGGACGGAGCAATTTATACTGTCGGATCTCCTATTGATTAC GGTGTGATCGTGGATACTAAAGCTTATAGCGGAGGTTATAATCTGCCAATTGGCCAAGCAGATGAAATGCAACGA TATGTCAAAGAAAATCAAACACGAAACAAACATATCAACCCTAATGAATGGTGGAAAGTCTATCCATCTTCTGTA ACGGAATTTAAGTTTTTATTTGTGAGTGGTCACTTTAAAGGAAACTACAAAGCTCAGCTTACACGATTAAATCAT AAGACTAATTGTAATGGAGCTGTTCTTAGTGTAGAAGAGCTTTTAATTGGTGGAGAAATGATTAAAGCCGGCACA TTAACCTTAGAGGAAGTGAGACGGAAATTTAATAACGGCGAGATAAACTTTTAA CCR5-224 (+) protein sequence (SEQ ID NO: 120): MDYKDHDGDYKDHDIDYKDDDDKMAPKKKRKVGIHGVPAAMAERPFQCRICMRNFSDRSNLSRHIRTHTGEKPFA CDICGRKFAISSNLNSHTKIHTGSQKPFQCRICMRNFSRSDNLARHIRTHTGEKPFACDICGRKFATSGNLTRHT KIHLRGSQLVKSELEEKKSELRHKLKYVPHEYIELIEIARNSTQDRILEMKVMEFFMKVYGYRGKHLGGSRKPDG AIYTVGSPIDYGVIVDTKAYSGGYNLPIGQADEMQRYVKENQTRNKHINPNEWWKVYPSSVTEFKFLFVSGHFKG NYKAQLTRLNHKTNCNGAVLSVEELLIGGEMIKAGTLTLEEVRRKFNNGEINF CCR5-224 (−) DNA sequence (SEQ ID NO: 121): TAATACGACTCACTATAGGGAGACCCAAGCTGGCTAGCCACCATGGACTACAAAGACCATGACGGTGATTATAAA GATCATGACATCGATTACAAGGATGACGATGACAAGATGGCCCCCAAGAAGAAGAGGAAGGTGGGCATTCACGGG GTACCTGCCGCTATGGCTGAGAGGCCCTTCCAGTGTCGAATCTGCATGCGTAACTTCAGTCGCTCCGACAACCTG TCCGTGCACATCCGCACCCACACAGGCGAGAAGCCTTTTGCCTGTGACATTTGTGGGAGGAAGTTTGCCCAGAAG ATCAACCTGCAGGTGCATACCAAGATACACACCGGCGAGAAGCCCTTCCAGTGTCGAATCTGCATGCGTAACTTC AGTCGCTCCGACGTGCTGTCCGAGCACATCCGCACCCACACAGGCGAGAAGCCTTTTGCCTGTGACATTTGTGGG AGGAAATTTGCCCAGCGCAACCACCGCACCACCCATACCAAGATACACCTGCGGGGATCCCAACTAGTCAAAAGT GAACTGGAGGAGAAGAAATCTGAACTTCGTCATAAATTGAAATATGTGCCTCATGAATATATTGAATTAATTGAA ATTGCCAGAAATTCCACTCAGGATAGAATTCTTGAAATGAAGGTAATGGAATTTTTTATGAAAGTTTATGGATAT AGAGGTAAACATTTGGGTGGATCAAGGAAACCGGACGGAGCAATTTATACTGTCGGATCTCCTATTGATTACGGT GTGATCGTGGATACTAAAGCTTATAGCGGAGGTTATAATCTGCCAATTGGCCAAGCAGATGAAATGGAGCGATAT GTCGAAGAAAATCAAACACGAAACAAACATCTCAACCCTAATGAATGGTGGAAAGTCTATCCATCTTCTGTAACG GAATTTAAGTTTTTATTTGTGAGTGGTCACTTTAAAGGAAACTACAAAGCTCAGCTTACACGATTAAATCATATC ACTAATTGTAATGGAGCTGTTCTTAGTGTAGAAGAGCTTTTAATTGGTGGAGAAATGATTAAAGCCGGCACATTA ACCTTAGAGGAAGTGAGACGGAAATTTAATAACGGCGAGATAAACTTTTAA CCR5-224 (−) protein sequence (SEQ ID NO: 122): MDYKDHDGDYKDHDIDYKDDDDKMAPKKKRKVGIHGVPAAMAERPFQCRICMRNFSRSDNLSVHIR THTGEKPFACDICGRKFAQKINLQVHTKIHTGEKPFQCRICMRNFSRSDVLSEHIRTHTGEKPFACDICG RKFAQRNHRTTHTKIHLRGSQLVKSELEEKKSELRHKLKYVPHEYIELIEIARNSTQDRILEMKVMEFF MKVYGYRGKHLGGSRKPDGAIYTVGSPIDYGVIVDTKAYSGGYNLPIGQADEMERYVEENQTRNKHL NPNEWWKVYPSSVIEFKFLFVSGHFKGNYKAQLTRLNHITNCNGAVLSVEELLIGGEMIKAGILTLEE VRRKFNNGEINF VF2468 (+) DNA sequence (SEQ ID NO: 123): TAATACGACTCACTATAGGGAGACCCAAGCTGGCTAGCCACCATGGACTACAAAGACCATGACGG TGATTATAAAGATCATGACATCGATTACAAGGATGACGATGACAAGATGGCCCCCAAGAAGAAGA GGAAGGTGGGCATTCACGGGGTGCCGTCTAGACCCGGGGAGCGCCCCTTCCAGTGTCGCATTTGC ATGCGGAACTTTTCGCGCCAGGACAGGCTTGACAGGCATACCCGTACTCATACCGGTGAAAAACC GTTTCAGTGTCGGATCTGTATGCGAAATTTCTCCCAGAAGGAGCACTTGGCGGGGCATCTACGTAC GCACACCGGCGAGAAGCCATTCCAATGCCGAATATGCATGCGCAACTTCAGTCGCCGCGACAACC TGAACCGGCACCTAAAAACCCACCTGAGGGGATCCCAACTAGTCAAAAGTGAACTGGAGGAGAA GAAATCTGAACTTCGTCATAAATTGAAATATGTGCCTCATGAATATATTGAATTAATTGAAATTGC CAGAAATTCCACTCAGGATAGAATTCTTGAAATGAAGGTAATGGAATTTTTTATGAAAGTTTATGG ATATAGAGGTAAACATTTGGGTGGATCAAGGAAACCGGACGGAGCAATTTATACTGTCGGATCTC CTATTGATTACGGTGTGATCGTGGATACTAAAGCTTATAGCGGAGGTTATAATCTGCCAATTGGCC AAGCAGATGAAATGCAACGATATGTCAAAGAAAATCAAACACGAAACAAACATATCAACCCTAAT GAATGGTGGAAAGTCTATCCATCTTCTGTAACGGAATTTAAGTTTTTATTTGTGAGTGGTCACTTTA AAGGAAACTACAAAGCTCAGCTTACACGATTAAATCATAAGACTAATTGTAATGGAGCTGTTCTTA GTGTAGAAGAGCTTTTAATTGGTGGAGAAATGATTAAAGCCGGCACATTAACCTTAGAGGAAGTG AGACGGAAATTTAATAACGGCGAGATAAACTTTTAA VF2468 (+) protein sequence (SEQ ID NO: 124): MDYKDHDGDYKDHDIDYKDDDDKMAPKKKRKVGIHGVPSRPGERPFQCRICMRNFSRQDRLDRHTR THTGEKPFQCRICMRNFSQKEHLAGHLRTHTGEKPFQCRICMRNFSRRDNLNRHLKTHLRGSQLVKSE LEEKKSELRHKLKYVPHEYIELIEIARNSTQDRILEMKVMEFFMKVYGYRGKHLGGSRKPDGAIYTVGS PIDYGVIVDTKAYSGGYNLPIGQADEMQRYVKENQTRNKHINPNEWWKVYPSSVTEFKFLFVSGHFKG NYKAQLTRLNHKTNCNGAVLSVEELLIGGEMIKAGTLTLEEVRRKFNNGEINF VF2468 (−) DNA sequence (SEQ ID NO: 125): TAATACGACTCACTATAGGGAGACCCAAGCTGGCTAGCCACCATGGACTACAAAGACCATGACGG TGATTATAAAGATCATGACATCGATTACAAGGATGACGATGACAAGATGGCCCCCAAGAAGAAGA GGAAGGTGGGCATTCACGGGGTGCCGTCTAGACCCGGGGAGCGCCCCTTCCAGTGTCGCATTTGC ATGCGGAACTTTTCGACCGGCCAGATCCTTGACCGCCATACCCGTACTCATACCGGTGAAAAACCG TTTCAGTGTCGGATCTGTATGCGAAATTTCTCCGTGGCGCACAGCTTGAAGAGGCATCTACGTACG CACACCGGCGAGAAGCCATTCCAATGCCGAATATGCATGCGCAACTTCAGTGACCCCAGCAACCT GCGGCGCCACCTAAAAACCCACCTGAGGGGATCCCAACTAGTCAAAAGTGAACTGGAGGAGAAG AAATCTGAACTTCGTCATAAATTGAAATATGTGCCTCATGAATATATTGAATTAATTGAAATTGCC AGAAATTCCACTCAGGATAGAATTCTTGAAATGAAGGTAATGGAATTTTTTATGAAAGTTTATGGA TATAGAGGTAAACATTTGGGTGGATCAAGGAAACCGGACGGAGCAATTTATACTGTCGGATCTCC TATTGATTACGGTGTGATCGTGGATACTAAAGCTTATAGCGGAGGTTATAATCTGCCAATTGGCCA AGCAGATGAAATGGAGCGATATGTCGAAGAAAATCAAACACGAAACAAACATCTCAACCCTAATG AATGGTGGAAAGTCTATCCATCTTCTGTAACGGAATTTAAGTTTTTATTTGTGAGTGGTCACTTTAA AGGAAACTACAAAGCTCAGCTTACACGATTAAATCATATCACTAATTGTAATGGAGCTGTTCTTAG TGTAGAAGAGCTTTTAATTGGTGGAGAAATGATTAAAGCCGGCACATTAACCTTAGAGGAAGTGA GACGGAAATTTAATAACGGCGAGATAAACTTTTAA VF2468 (−) protein sequence (SEQ ID NO: 126): MDYKDHDGDYKDHDIDYKDDDDKMAPKKKRKVGIHGVPSRPGERPFQCRICMRNFSTGQILDRHTRT HTGEKPFQCRICMRNFSVAHSLKRHLRTHTGEKPFQCRICMRNFSDPSNLRRHLKTHLRGSQLVKSELE EKKSELRHKLKYVPHEYIELIEIARNSTQDRILEMKVMEFFMKVYGYRGKHLGGSRKPDGAIYTVGSPI DYGVIVDTKAYSGGYNLPIGQADEMERYVEENQTRNKHLNPNEWWKVYPSSVTEFKFLFVSGHFKGN YKAQLTRLNHITNCNGAVLSVEELLIGGEMIKAGILTLEEVRRKFNNGEINF

Library Construction.

Libraries of target sites were incorporated into double-stranded DNA by PCR with Taq DNA Polymerase (NEB) on a pUC19 starting template with primers “N5-PvuI” and “CCR5-224-N4,” “CCR5-224-N5,” “CCR5-224-N6,” “CCR5-224-N7,” “VF2468-N4,” “VF2468-N5,” “VF2468-N6,” or “VF2468-N7,” yielding an approximately 545-bp product with a PvuI restriction site adjacent to the library sequence, and purified with the Qiagen PCR Purification Kit.

Library-encoding oligonucleotides were of the form 5′ backbone-PvuI site-NNNNNN-partially randomized half-site-N₄₋₇-partially randomized half site-N-backbone 3′. The purified oligonucleotide mixture (approximately 10 μg) was blunted and phosphorylated with a mixture of 50 units of T4 Polynucleotide Kinase and 15 units of T4 DNA polymerase (NEBNext End Repair Enzyme Mix, NEB) in 1×NEBNext End Repair Reaction Buffer (50 mM Tris-HCl, 10 mM MgCl₂, 10 mM dithiothreitol, 1 mM ATP, 0.4 mM dATP, 0.4 mM dCTP, 0.4 mM dGTP, 0.4 mM dTTP, pH 7.5) for 1.5 hours at room temperature. The blunt-ended and phosphorylated DNA was purified with the Qiagen PCR Purification Kit according to the manufacturer's protocol, diluted to 10 ng/μL in NEB T4 DNA Ligase Buffer (50 mM Tris-HCl, 10 mM MgCl₂, 10 mM dithiothreitol, 1 mM ATP, pH 7.5) and circularized by ligation with 200 units of T4 DNA ligase (NEB) for 15.5 hours at room temperature. Circular monomers were gel purified on 1% TAE-Agarose gels. 70 ng of circular monomer was used as a substrate for rolling-circle amplification at 30° C. for 20 hours in a 100 μL reaction using the Illustra TempliPhi 100 Amplification Kit (GE Healthcare). Reactions were stopped by incubation at 65° C. for 10 minutes. Target site libraries were quantified with the Quant-iT PicoGreen dsDNA Reagent (Invitrogen). Libraries with N₄, N₅, N₆, and N₇ spacer sequences between partially randomized half-sites were pooled in equimolar concentrations for both CCR5-224 and VF2468.

Zinc Finger Nuclease Expression and Characterization.

3×FLAG-tagged zinc finger proteins for CCR5-224 and VF2468 were expressed as fusions to FokI obligate heterodimers³⁰ in mammalian expression vectors⁴ derived from pMLM290 and pMLM292. DNA and protein sequences are provided elsewhere herein. Complete vector sequences are available upon request. 2 μg of ZFN-encoding vector was transcribed and translated in vitro using the TNT Quick Coupled rabbit reticulocyte system (Promega). Zinc chloride (Sigma-Aldrich) was added at 500 μM and the transcription/translation reaction was performed for 2 hours at 30° C. Glycerol was added to a 50% final concentration. Western blots were used to visualize protein using the anti-FLAG M2 monoclonal antibody (Sigma-Aldrich). ZFN concentrations were determined by Western blot and comparison with a standard curve of N-terminal FLAG-tagged bacterial alkaline phosphatase (Sigma-Aldrich).

Test substrates for CCR5-224 and VF2468 were constructed by cloning into the HindIII/XbaI sites of pUC19. PCR with primers “test fwd” and “test rev” and Taq DNA polymerase yielded a linear 1 kb DNA that could be cleaved by the appropriate ZFN into two fragments of sizes ˜300 bp and ˜700 bp. Activity profiles for the zinc finger nucleases were obtained by modifying the in vitro cleavage protocols used by Miller et al.³⁰ and Cradick et al.³¹. 1 μg of linear 1 kb DNA was digested with varying amounts of ZFN in 1×NEBuffer 4 (50 mM potassium acetate, 20 mM Tris-acetate, 10 mM magnesium acetate, 1 mM dithiothreitol, pH 7.9) for 4 hours at 37° C. 100 μg of RNase A (Qiagen) was added to the reaction for 10 minutes at room temperature to remove RNA from the in vitro transcription/translation mixture that could interfere with purification and gel analysis. Reactions were purified with the Qiagen PCR Purification Kit and analyzed on 1% TAE-agarose gels.

In Vitro Selection.

ZFNs of varying concentrations, an amount of TNT reaction mixture without any protein-encoding DNA template equivalent to the greatest amount of ZFN used (“lysate”), or 50 units PvuI (NEB) were incubated with 1 μg of rolling-circle amplified library for 4 hours at 37° C. in 1×NEBuffer 4 (50 mM potassium acetate, 20 mM Tris-acetate, 10 mM magnesium acetate, 1 mM dithiothreitol, pH 7.9). 100 μg of RNase A (Qiagen) was added to the reaction for 10 minutes at room temperature to remove RNA from the in vitro transcription/translation mixture that could interfere with purification and gel analysis. Reactions were purified with the Qiagen PCR Purification Kit. 1/10 of the reaction mixture was visualized by gel electrophoresis on a 1% TAE-agarose gel and staining with SYBR Gold Nucleic Acid Gel Stain (Invitrogen).

The purified DNA was blunted with 5 units DNA Polymerase I, Large (Klenow) Fragment (NEB) in 1×NEBuffer 2 (50 mM NaCl, 10 mM Tris-HCl, 10 mM MgCl₂, 1 mM dithiothreitol, pH 7.9) with 500 μM dNTP mix (Bio-Rad) for 30 minutes at room temperature. The reaction mixture was purified with the Qiagen PCR Purification Kit and incubated with 5 units of Klenow Fragment (3′ exo⁻) (NEB) for 30 minutes at 37° C. in 1×NEBuffer 2 (50 mM NaCl, 10 mM Tris-HCl, 10 mM MgCl₂, 1 mM dithiothreitol, pH 7.9) with 240 μM dATP (Promega) in a 50 μL final volume. 10 mM Tris-HCl, pH 8.5 was added to a volume of 90 μL and the reaction was incubated for 20 minutes at 75° C. to inactivate the enzyme before cooling to 12° C. 300 fmol of “adapter1/2”, barcoded according to enzyme concentration, or 6 pmol of “adapter1/2” for the PvuI digest, were added to the reaction mixture, along with 10 ul 10×NEB T4 DNA Ligase Reaction Buffer (500 mM Tris-HCl, 100 mM MgCl₂, 100 mM dithiothreitol, 10 mM ATP). Adapters were ligated onto the blunt DNA ends with 400 units of T4 DNA ligase at room temperature for 17.5 hours and ligated DNA was purified away from unligated adapters with Illustra Microspin S-400 HR sephacryl columns (GE Healthcare). DNA with ligated adapters were amplified by PCR with 2 units of Phusion Hot Start II DNA Polymerase (NEB) and 10 pmol each of primers “PE1” and “PE2” in 1× Phusion GC Buffer supplemented with 3% DMSO and 1.7 mM MgCl₂. PCR conditions were 98° C. for 3 min, followed by cycles of 98° C. for 15 s, 60° C. for 15 s, and 72° C. for 15 s, and a final 5 min extension at 72° C. The PCR was run for enough cycles (typically 20-30) to see a visible product on gel. The reactions were pooled in equimolar amounts and purified with the Qiagen PCR Purification Kit. The purified DNA was gel purified on a 1% TAE-agarose gel, and submitted to the Harvard Medical School Biopolymers Facility for Illumina 36-base paired-end sequencing.

Data Analysis.

Illumina sequencing reads were analyzed using programs written in C++. Algorithms are described elsewhere herein (e.g., Protocols 1-9), and the source code is available on request. Sequences containing the same barcode on both paired sequences and no positions with a quality score of ‘B’ were binned by barcode. Half-site sequence, overhang and spacer sequences, and adjacent randomized positions were determined by positional relationship to constant sequences and searching for sequences similar to the designed CCR5-224 and VF2468 recognition sequences. These sequences were subjected to a computational selection step for complementary, filled-in overhang ends of at least 4 base pairs, corresponding to rolling-circle concatemers that had been cleaved at two adjacent and identical sites. Specificity scores were calculated with the formulae: positive specificity score=(frequency of base pair at position[post-selection]−frequency of base pair at position[pre-selection])/(1−frequency of base pair at position[pre-selection]) and negative specificity score=(frequency of base pair at position[post-selection]−frequency of base pair at position[pre-selection])/(frequency of base pair at position[pre-selection]).

Positive specificity scores reflect base pairs that appear with greater frequency in the post-selection library than in the starting library at a given position; negative specificity scores reflect base pairs that are less frequent in the post-selection library than in the starting library at a given position. A score of +1 indicates an absolute preference, a score of −1 indicates an absolute intolerance, and a score of 0 indicates no preference.

Assay of Genome Modification at Cleavage Sites in Human Cells.

CCR5-224 ZFNs were cloned into a CMV-driven mammalian expression vector in which both ZFN monomers were translated from the same mRNA transcript in stoichiometric quantities using a self-cleaving T2A peptide sequence similar to a previously described vector³². This vector also expresses enhanced green fluorescent protein (eGFP) from a PGK promoter downstream of the ZFN expression cassette. An empty vector expressing only eGFP was used as a negative control.

To deliver ZFN expression plasmids into cells, 15 μg of either active CCR5-224 ZFN DNA or empty vector DNA were used to Nucleofect 2×10⁶ K562 cells in duplicate reactions following the manufacturer's instructions for Cell Linc Nucleofector Kit V (Lonza). GFP-positive cells were isolated by FACS 24 hours post-transfection, expanded, and harvested five days post-transfection with the QIAamp DNA Blood Mini Kit (Qiagen).

PCR for 37 potential CCR5-224 substrates and 97 potential VF2468 substrates was performed with Phusion DNA Polymerase (NEB) and primers “[ZFN] [#] fwd” and “[ZFN] [#] rev” (Table 9) in 1× Phusion HF Buffer supplemented with 3% DMSO. Primers were designed using Primer3³³. The amplified DNA was purified with the Qiagen PCR Purification Kit, eluted with 10 mM Tris-HCl, pH 8.5, and quantified by 1K Chip on a LabChip GX instrument (Caliper Life Sciences) and combined into separate equimolar pools for the catalytically active and empty vector control samples. PCR products were not obtained for 3 CCR5 sites and 7 VF2468 sites, which excluded these samples from further analysis. Multiplexed Illumina library preparation was performed according to the manufacturer's specifications, except that AMPure XP beads (Agencourt) were used for purification following adapter ligation and PCR enrichment steps. Illumina indices 11 (“GGCTAC”) and 12 (“CTTGTA”) were used for ZFN-treated libraries while indices 4 (“TGACCA”) and 6 (“GCCAAT”) were used for the empty vector controls. Library concentrations were quantified by KAPA Library Quantification Kit for Illumina Genome Analyzer Platform (Kapa Biosystems). Equal amounts of the barcoded libraries derived from active- and empty vector-treated cells were diluted to 10 nM and subjected to single read sequencing on an Illumina HiSeq 2000 at the Harvard University FAS Center for Systems Biology Core facility. Sequences were analyzed using Protocol 9 for active ZFN samples and empty vector controls.

Statistical Analysis.

In FIG. 8, P-values were calculated for a one-sided test of the difference in the means of the number of target site mutations in all possible pairwise comparisons among pre-selection, 0.5 nM post-selection, 1 nM post-selection, 2 nM post-selection, and 4 nM post-selection libraries for CCR5-224 or VF2468. The t-statistic was calculated as t=(x_bar₁−x_bar₂)/sqrt(1×p_hat₁×(1−p_hat₁)/n₁+1×p_hat₂×(1−p_hat₂)/n₁), where x_bar₁ and x_bar₂ are the means of the distributions being compared, l is the target site length (24 for CCR5-224; 18 for VF2468), p_hat₁ and p_hat₂ are the calculated probabilities of mutation (x_bar/l) for each library, and n₁ and n₂ are the total number of sequences analyzed for each selection (Table 2). All pre- and post-selection libraries were assumed to be binomially distributed.

In Tables 4 and 7, P-values were calculated for a one-sided test of the difference in the proportions of sequences with insertions or deletions from the active ZFN sample and the empty vector control samples. The t-statistic was calculated as t=(p_hat₁−p_hat₂)/sqrt((p_hat₁×(1−p_hat₁)/n₁)+(p_hat₂×(1−p_hat₂)/n₂)), where p_hat₁ and n₁ are the proportion and total number, respectively, of sequences from the active sample and p_hat₂ and n₂ are the proportion and total number, respectively, of sequences from the empty vector control sample.

Plots.

All heat maps were generated in the R software package with the following command: image([variable], zlim=c(−1,1), col=colorRampPalette(c(“red”,“white”,“blue”),space=“Lab”)(2500)

Protocol 1: Quality Score Filtering and Sequence Binning.

1) search each position of both pairs of sequencing read for quality score, reject if any position has quality score=‘B’

2) output to separate files all sequence reads where the first sequence in the pair start with barcodes (“AAT”, “ATA”, “TAA”, “CAC”, “TCG”) and count the number of sequences corresponding to each barcode

Protocol 2: Filtering by ZFN (“AAT”, “ATA”, “TAA”, “CAC”)

For each binned file,

1) accept only sequence pairs where both sequences in the pair start with the same barcode

2) identify orientation of sequence read by searching for constant regions

orientation 1 is identified by the constant region “CGATCGTTGG” (SEQ ID NO:127)

orientation 2 is identified by the constant region “CAGTGGAACG” (SEQ ID NO:128)

3) search sequences from position 4 (after the barcode) up to the first position in the constant region for the subsequence that has the fewest mutations compared to the CCR5-224 and VF2468 half site that corresponds to the identified constant region

search sequences with orientation 1 for “GATGAGGATGAC” (SEQ ID NO:129) (CCR5-224(+)) and “GACGCTGCT” (SEQ ID NO:130) (VF2468(−))

search sequences with orientation 2 for “AAACTGCAAAAG” (SEQ ID NO:131) (CCR5-224(−)) and “GAGTGAGGA” (SEQ ID NO:132) (VF2468(+))

4) bin sequences as CCR5-224 or VF2468 by testing for the fewest mutations across both half-sites

5) the positions of the half-sites and constant sequences are used to determine the overhang/spacer sequences, the flanking nucleotide sequences, and the tag sequences

the subsequence between the half-site of orientation 1 and the constant region is the tag sequence

-   -   if there is no tag sequence, the tag sequence is denoted by ‘X’

the overhang sequence is determined by searching for the longest reverse-complementary subsequences between the subsequences of orientation 1 and orientation 2 that start after the barcodes

the spacer sequence is determined by concatenating the reverse complement of the subsequence in orientation 1 that is between the overhang and the half-site (if any), the overhang, and the subsequence in orientation 2 that is between the overhang and the halfsite

-   -   if there is overlap between the overhang and half-site, only the         non-overlapping subsequence present in the overhang is counted         as part of the spacer         6) to remove duplicate sequences, sort each sequence pair into a         tree

each level of the tree corresponds to a position in the sequence

each node at each level corresponds to a particular base (A, C, G, T, or X=not(A, C, G, or T)) and points to the base of the next position (A, C, G, T, X)

the sequence pairs are encoded in the nodes and a subsequence consisting of the concatenation of the spacer sequence, flanking nucleotide sequence, and tag sequence is sorted in the tree

at the terminal nodes of the tree, each newly entered sequence is compared to all other sequences in the node to avoid duplication

7) the contents of the tree are recursively outputted into separate files based on barcode and ZFN

Protocol 3: Library Filtering (“TCG”)

1) accept only sequence pairs where both sequences in the pair start with the same barcode

2) analyze the sequence pair that does not contain the sequence “TCGTTGGGAACCGGAGCTGAATGAAGCCATACCAAACGAC” (SEQ ID NO:133) (the other pair contains the library sequence)

3) search sequences for ZFN half-sites and bin by the ZFN site that has fewer mutations

search for “GTCATCCTCATC” (SEQ ID NO:134) and “AAACTGCAAAAG” (SEQ ID NO:135) (CCR5-224) and “AGCAGCGTC” (SEQ ID NO:136) and “GAGTGAGGA” (SEQ ID NO:137) (VF2468)

4) identify the spacer, flanking nucleotide, and nucleotide tag sequences based on the locations of the half-sites

5) use the tree algorithm in step 6 under Filtering by ZFN to eliminate duplicate sequences

Protocol 4: Sequence Profiles

1) analyze only sequences that contain no ‘N’ positions and have spacer lengths between 4 and 7

2) tabulate the total number of mutations, the spacer length, the overhang length, the nucleotide frequencies for the (+) and (−) half-sites, the nucleotide frequencies for spacers that are 4-bp, 5-bp, 6-bp, and 7-bp long, and the nucleotide frequencies for the flanking nucleotide and the tag sequence 3) repeat steps 1 and 2 for library sequences 4) calculate specificity scores at each position using positive specificity score=(frequency of base pair at position[post-selection]−frequency of base pair at position[pre-selection])/(1−frequency of base pair at position[pre-selection]) negative specificity score=(frequency of base pair at position[post-selection]−frequency of base pair at position[pre-selection])/(frequency of base pair at position[pre-selection])

Protocol 5: Genomic Matches

1) the human genome sequence was searched with 24 and 25 base windows (CCR5-224) and 18 and 19 base windows (VF2468) for all sites within nine mutations (CCR5-224) or six mutations (VF2468) of the canonical target site with all spacer sequences of five or six bases being accepted 2) each post-selection sequence was compared to the set of genomic sequences within nine and six mutations of CCR5-224 and VF2468, respectively

Protocol 6: Enrichment Factors for Sequences with 0, 1, 2, or 3 Mutations

1) for each sequence, divide the frequency of occurrence in the post-selection library by the frequency of occurrence in the pre-selection library

Protocol 7: Filtered Sequence Profiles

1) use the algorithm described above in Sequence profiles, except in addition, only analyze sequences with off-target bases at given positions for both pre- and post-selection data

Protocol 8: Compensation Difference Map

1) use Filtered sequence profiles algorithm for mutation at every position in both half-sites

2) calculate Δ(specificity score)=filtered specificity score−non-filtered specificity score

Protocol 9: NHEJ Search

1) identify the site by searching for exact flanking sequences

2) count the number of inserted or deleted bases by comparing the length of the calculated site to the length of the expected site and by searching for similarity to the unmodified target site (sequences with 5 or fewer mutations compared to the intended site were counted as unmodified) 3) inspect all sites other than CCR5, CCR2, and VEGF-A promoter by hand to identify true insertions or deletions

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Unexpected failure rates for modular     assembly of engineered zinc fingers. Nat Methods 5, 374-5 (2008). -   27. Shimizu, Y. et al. Adding Fingers to an Engineered Zinc Finger     Nuclease Can Reduce Activity. Biochemistry 50, 5033-41 (2011). -   28. Bibikova, M. et al. Stimulation of homologous recombination     through targeted cleavage by chimeric nucleases. Mol Cell Biol 21,     289-97 (2001). -   29. Handel, E. M., Alwin, S. & Cathomen, T. Expanding or restricting     the target site repertoire of zinc-finger nucleases: the     inter-domain linker as a major determinant of target site     selectivity. Mol Ther 17, 104-11 (2009). -   30. Miller, J. C. et al. An improved zinc-finger nuclease     architecture for highly specific genome editing. Nat Biotechnol 25,     778-85 (2007). -   31. Cradick, T. J., Keck, K., Bradshaw, S., Jamieson, A. C. &     McCaffrey, A. P. Zinc-finger nucleases as a novel therapeutic     strategy for targeting hepatitis B virus DNAs. Mol Ther 18, 947-54     (2010). -   32. Doyon, Y. et al. Heritable targeted gene disruption in zebrafish     using designed zinc-finger nucleases. Nat Biotechnol 26, 702-8     (2008). -   33. Rozen, S. & Skaletsky, H. Primer3 on the WWW for general users     and for biologist programmers. Methods Mol Biol 132, 365-86 (2000).

All publications, patents and sequence database entries mentioned herein, including those items listed above, are hereby incorporated by reference in their entirety as if each individual publication or patent was specifically and individually indicated to be incorporated by reference. In case of conflict, the present application, including any definitions herein, will control.

Example 2—TALENs

The site preferences of different TALENs were profiled in analogy to the work done for ZFN profiling described above. The experiments and results are described in FIGS. 19-49. Selection 1 included a comparison between TALENs having a +28 vs. a +63 linker. Selection 2 included a comparison of TALENs of different TAL domain length.

TAL DNA binding domains are the basis of a transformative technology to specifically modulate target DNA both in vitro and in cells. The designable TAL DNA binding domains have advantages in targetable sequence space and ease of construction compared to other DNA binding domains, for example, zinc fingers. These TAL DNA binding domains are comprised of repeats of a 34 amino acid domain with a highly variable di-amino acid (RVD) coding for recognition of a single base pair in the target DNA sequence (FIG. 20). Based on the robustness of this RVD code and the crystal structure of a TAL bound to its DNA target, it is likely that binding of a single repeat to a base pair is relatively independent of adjacent repeat binding. The TAL DNA binding domain (an array of repeats) can be linked to the monomer of a heterodimeric nuclease domain to form a TAL nuclease. Thus, two distinct TAL nucleases can hind adjacent target half sites to cleave a specific sequence resulting in genome modifications in vivo (FIGS. 19 and 20). While a number of studies have investigated the specificity of TAL DNA binding, to our knowledge no studies have profiled the specificity of TAL nucleases on a large scale. We applied the concept of high-throughput, in vitro selection for nuclease specificity outlined for ZFNs in Example 1 to TAL nucleases to both confirm the modular, independent binding of TAL repeats expected from their easy design-ability and also identify genomic off-target sequences cut by therapeutically relevant TAL nucleases.

The selection scheme for profiling the specificity of TAL nucleases via in vitro library screening was in analogy to the selection scheme described for ZFNs in Example. Detailed protocols are provided below:

Preparation of Library of Partly Randomized Target Sites

2 ul of 10 pmol TALNCCR5 Library Oligo (separate reactions for each oligo)

2 ul 10× CircLigase II 10× Reaction Buffer

1 ul 50 mM MnCl2

1 ul CircLigase II ssDNA Ligase (100 U) [Epicentre]

X ul water to 20 uL total volume

Incubate 16 hrs at 60° C. Incubate 10 min at 85° C. to inactivate.

Add 2.5 ul of each Circligase II reaction (without purification)

Add 25 ul TempliPhi™ [GE Healthcare] 100 sample buffer.

Incubate 3 min at 95° C. Slow cool to 4° C.

Add 25 ul TempliPhi™ reaction buffer/1 ul enzyme mix.

Incubate 16 hrs at 30° C. Heat inactive 10 min at 55° C.

Quantify amount of dsDNA using Quant-iT™ PicoGreen® dsDNA [Invitrogen]

Combine equal moles of TempliPhi™ reactions to final 2 uM with respect to number of cut sites.

TALN Expression

16 ul TnT® Quick Coupled [Promega]

0.4 ul 1 mM methionine

2 uL of 0.8 ug TALN vector expression plasmid or water for empty lysate

1.6 uL of water

Incubate at 30 for 1.5 hours and then store at 4° C. overnight.

Quantify amount of TALN in lysate via Western Blot.

TALN Digestion

25 uL of 10×NEB Buffer 3 [New England Biolabs]

10 uL of 2 uM TempliPh Library DNA

165 uL water

Add left TALN lysate to 20 nM total left TALN

Add right TALN lysate to 20 nM total right TALN

Add empty lysate to total of 50 uL lysate

Incubate 2 hrs at 37° C. Add 5 ul (50 ug) RNaseA (Qiagen). Incubate 10 min at RT. Purify with Qiagen PCR Purification Kit. Elute in 50 uL of 1 mM Tris, pH 8.0.

Adapter Ligation, PCR and Gel Purification of TALN Digestion

50 ul digested DNA

3 ul dNTP mix

6 ul NEB 2

1 ul Klenow [New England Biolabs]

Incubate 30 min at RT. Purify with Qiagen PCR Purification Kit.

50 ul eluted DNA

5.9 ul T4 DNA Ligase Buffer (NEB)

2 ul (20 pmol) heat/cooled adapter (different adapter for each selection)

1 ul T4 DNA ligase (NEB, 400 units)

Incubate at RT for 20 hrs. Purify with Qiagen PCR Purification Kit.

6 uL of TALN digested DNA

30 uL of 5× Buffer HF

1.5 uL 100 uM Illumina_fwd Primer

1.5 uL 100 uM PE_TALN_rev1 Primer

3 uL 10 mM dNTP

1.5 uL Phusion Hot Start II

106.5 uL of water

98° C. for 3 min, do 15 cycles of 98° C. for 15 s, 60° C. for 15 s, 72° C. for 1 min. Purify with Qiagen PCR Purification Kit

Gel Purify on 2% Agarose gel loading 1 ug of eluted DNA in 40 uL of 10% glycerol. Run on gel at 135V for 35 min. Gel purify bands of the length corresponding to a cut half site+full half site+adapter with filter paper. Remove filter paper and collect supernatant. Purify with Qiagen PCR Purification Kit.

6 uL of TALN digested DNA (5-26-12)

30 uL of 5× Buffer HF

1.5 uL 100 uM Illumina_fwd Primer

1.5 uL 100 uM PE_TALN_rev2 Primer

3 uL 10 mM dNTP

1.5 uL Phusion Hot Start II

106.5 uL of water

98° C. for 3 min, do 6 cycles of 98° C. for 15 s, 60° C. for 15 s, 72° C. for 1 min. Purify with Qiagen PCR Purification Kit.

Preparation of Pre-Selection Library

25 uL of 10×NEB Buffer 4

10 uL of 2 uM TempliPhi Library DNA

165 uL water

5 uL of Appropriate Restriction Enzyme [New England Biolabs]

210 uL of water

Incubate 1 hrs at 37° C. Purify with Qiagen PCR Purification Kit.

50 ul eluted DNA

5.9 ul T4 DNA Ligase Buffer (NEB)

2 ul (20 pmol) heat/cooled adapter (pool of 4 adapter sequences)

1 ul T4 DNA ligase (NEB, 400 units)

Incubate at RT for 20 hrs. Purify with Qiagen PCR Purification Kit.

6 uL of Restriction Enzyme Digested DNA (5-26-12)

30 uL of 5× Buffer HF

1.5 uL 100 uM Illumina_rev Primer

1.5 uL 100 uM TALNLibPCR Primer

3 uL 10 mM dNTP

1.5 uL Phusion Hot Start II

106.5 uL of water

98° C. for 3 min, 12 cycles of 98° C. for 15 s, 60° C. for 15 s, 72° C. for 1 min. Purify with Qiagen PCR Purification Kit

High-Throughput Sequencing

Quantify via RT-qPCR

12.5 uL of IQ SYBR Green Supermix

1 uL of 10 uM Illumina_rev

1 uL of 10 uM Illumina_fwd

9.5 uL of water

1 uL of DNA template (both Pre-Selection Library and TALN Digestion)

95° C. for 5 min, do 30 cycles of 95° C. for 30 s, 65° C. for 30 s, 72° C. for 40 s.

Dilute DNA to 2 nM (compared to sequencing standard)

5 uL of TALN Digestion 2 nM DNA

2.5 uL of Pre-Selection Library 2 nM DNA

10 uL of 0.1N NaOH

Incubate at room temp for 5 min

Sequence via Illumina Mi-Seq

Computational Filtering

For TALN Digested sequences, find two appropriately spaced constant oligo sequences

For Pre-selection Library sequences, find appropriately spaced constant oligo sequence and library adapter sequence

Parse sequence into cut overhang, left half site, spacer, right half site

Remove sequences with poor Illumina base scores in half sites (<B=rejected)

Primer Sequences

Primer Sequence J61TALCCR5B_10 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNN(N2)(N3) (N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1)(N2)(N3)NCCTCGGG ACT (SEQ ID NOs: 138 and 139) J63TALCCR5B_12 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNN(N2) (N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1)(N2)(N3)NCCTC GGGACT (SEQ ID NOs: 140 and 141) J65TALCCR5B_14 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNNNN (N2)(N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1)(N2)(N3)NCC TCGGGACT (SEQ ID NOs: 142 and 143) J66TALCCR5B_15 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNNNNN (N2)(N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1)(N2)(N3)NC CTCGGGACT (SEQ ID NOs: 144 and 145) J67TALCCR5B_16 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNNNNN N(N2)(N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1)(N2)(N3)N CCTCGGGACT (SEQ ID NOs: 146 and 147) J68TALCCR5B_17 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNNNNN NN(N2)(N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1)(N2)(N3) NCCTCGGGACT (SEQ ID NOs: 148 and 149) J69TALCCR5B_18 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNNNNN NNN(N2)(N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1)(N2)(N3) NCCTCGGGACT (SEQ ID NOs: 150 and 151) J71TALCCR5B_20 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNNNNN NNNNN(N2)(N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1)(N2) (N3)NCCTCGGGACT (SEQ ID NOs: 152 and 153) J73TALCCR5B_22 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNNNNN NNNNNNN(N2)(N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3)(N1) (N2)(N3)NCCTCGGGACT (SEQ ID NOs: 154 and 155) J75TALCCR5B_24 CCACGCTN(N1: 07070779)(N2: 07790707)(N1)(N1)(N2)(N3: 79070707)(N1) (N1)(N3)(N2)(N3)(N2)(N2)(N1)(N4: 07077907)(N2)NNNNNNNNNNNNNNN NNNNNNNNN(N2)(N3)(N1)(N3)(N2)(N3)(N4)(N1)(N2)(N3)(N4)(N1)(N3) (N1)(N2)(N3)NCCTCGGGACT (SEQ ID NOs: 156 and 157) CGTAAadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTCGTAA (SEQ ID NO: 158) CGTAAadapterREV TTACGAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 159) GTACTadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTFTCCCTACACGACG CTCTTCCGATCTGTACT (SEQ ID NO: 160) GTACTadapterREV AGTACAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 161) TACGAadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTTACGA (SEQ ID NO: 162) TACGAadapterREV TCGTAAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 163) ATGCTadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTATGCT (SEQ ID NO: 164) ATGCTadapterREV AGCATAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 165) TGCAAadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTTGCAA (SEQ ID NO: 166) TGCAAadapterREV TTGCAAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 167) GCATTadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTGCATT (SEQ ID NO: 168) GCATTadapterREV AATGCAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 169) GACTAadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTGACTA (SEQ ID NO: 170) GACTAadapterREV TAGTCAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 171) ACTGTadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTACTGT (SEQ ID NO: 172) ACTGTadapterREV ACAGTAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 173) CTGAAadapterfwd AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTCTGAA (SEQ ID NO: 174) CTGAAadapterREV TTCAGAGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGTAGATCTCG GTGG (SEQ ID NO: 175) PE_TALCCR5B_rev1 CAAGCAGAAGACGGCATACGAGATCGTGATGTGACTGGAGTTCAGA CGTGTGCTCTTCCG (SEQ ID NO: 176) PE_TALCCR5B_rev2 CAGACGTGTGCTCTTCCGATCNNNNAGCGTGGAGTCCCGAGG (SEQ ID NO: 177) PE_TALCCR5B_rev CAAGCAGAAGACGGCATACGAGATACAGTCGTGACTGGAGTTCAGA CGTGTGCTCTTCCGATCNNNNAGCGTGGAGTCCCGAGG (SEQ ID NO: 178) PE_TALCCR5Blib TCGGGAACGTGATCGGAAGAGCACACGTCTGAACTCCAGTCACCGT adapter1 CTAATCTCGTATGCCGTCTTCTGCTTG (SEQ ID NO: 179) PE_TALCCR5Blib GTGACTGGAGTTCAGACGTGTGCTCTTCCGATCACGTT (SEQ ID adapterrev1 NO: 180) PE_TALCCR5Blib TCGGGACGTAGATCGGAAGAGCACACGTCTGAACTCCAGTCACCGT adapter2 CTAATCTCGTATGCCGTCTTCTGCTTG (SEQ ID NO: 181) PE_TALCCR5Blib GTGACTGGAGTTCAGACGTGTGCTCTTCCGATCTACGT (SEQ ID adapterrev2 NO: 182) PE_TALCCR5Blib TCGGGAGTACGATCGGAAGAGCACACGTCTGAACTCCAGTCACCGT adapter3 CTAATCTCGTATGCCGTCTTCTGCTTG (SEQ ID NO: 183) PE_TALCCR5Blib GTGACTGGAGTTCAGACGTGTGCTCTTCCGATCGTACT (SEQ ID adapterrev3 NO: 184) PE_TALCCR5Blib TCGGGATACGGATCGGAAGAGCACACGTCTGAACTCCAGTCACCGT adapter4 CTAATCTCGTATGCCGTCTTCTGCTTG (SEQ ID NO: 185) PE_TALCCR5Blib GTGACTGGAGTTCAGACGTGTGCTCTTCCGATCCGTAT (SEQ ID adapterrev4 NO: 186) TALCCR5BlibPCR AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACG CTCTTCCGATCTNNNNCCTCGGGACTCCACGCT (SEQ ID NO: 187) IlluminaFwd AATGATACGGCGACCAC (SEQ ID NO: 188) IlluminaRev CAAGCAGAAGACGGCATACGA (SEQ ID NO: 189)

CONCLUSIONS

The relatively regular (log relationship) trend between number of half sites mutations and enrichment is consistent with a single TAL repeat binding a base pair independent of other repeat binding. A single mutation in the cleavage site does not significantly alter the distribution of other mutations in the compensation difference analysis suggesting that the TAL repeat domains bind independently. The +28 linker is more specific than the +63 linker TALN constructs. While TALNs recognizing larger target sites are less specific in that they can tolerate more mutations, the abundance of the mutant larger sequences is less than the increase in enrichment, thus the in vitro selection data and abundance of off-target sites indicates off-target cleavage to be significantly less likely in longer TALN pairs. Combining the regular decrease of cleavage efficiency (enrichment) as total target site mutations increase and the enrichment at each position it is possible to predict the off-target site cleavage of any sequence. For the most part, in the TALN selection the enrichment was dependent on the total mutations in both half sites and not on the distribution of mutations between half sites as was observed for zinc finger nucleases (ZFN). This observation combined with the context dependent binding of ZFNs indicated that TALENs may readily be engineered to a specificity as high or higher than their ZFN equivalents.

All publications, patents and sequence database entries mentioned herein, including those items listed above, are hereby incorporated by reference in their entirety as if each individual publication or patent was specifically and individually indicated to be incorporated by reference. In case of conflict, the present application, including any definitions herein, will control.

EQUIVALENTS AND SCOPE

Those skilled in the art will recognize, or be able to ascertain using no more than routine experimentation, many equivalents to the specific embodiments of the invention described herein. The scope of the present invention is not intended to be limited to the above description, but rather is as set forth in the appended claims.

In the claims articles such as “a,” “an,” and “the” may mean one or more than one unless indicated to the contrary or otherwise evident from the context. Claims or descriptions that include “or” between one or more members of a group are considered satisfied if one, more than one, or all of the group members are present in, employed in, or otherwise relevant to a given product or process unless indicated to the contrary or otherwise evident from the context. The invention includes embodiments in which exactly one member of the group is present in, employed in, or otherwise relevant to a given product or process. The invention also includes embodiments in which more than one, or all of the group members are present in, employed in, or otherwise relevant to a given product or process.

Furthermore, it is to be understood that the invention encompasses all variations, combinations, and permutations in which one or more limitations, elements, clauses, descriptive terms, etc., from one or more of the claims or from relevant portions of the description is introduced into another claim. For example, any claim that is dependent on another claim can be modified to include one or more limitations found in any other claim that is dependent on the same base claim. Furthermore, where the claims recite a composition, it is to be understood that methods of using the composition for any of the purposes disclosed herein are included, and methods of making the composition according to any of the methods of making disclosed herein or other methods known in the art are included, unless otherwise indicated or unless it would be evident to one of ordinary skill in the art that a contradiction or inconsistency would arise.

Where elements are presented as lists, e.g., in Markush group format, it is to be understood that each subgroup of the elements is also disclosed, and any element(s) can be removed from the group. It is also noted that the term “comprising” is intended to be open and permits the inclusion of additional elements or steps. It should be understood that, in general, where the invention, or aspects of the invention, is/are referred to as comprising particular elements, features, steps, etc., certain embodiments of the invention or aspects of the invention consist, or consist essentially of, such elements, features, steps, etc. For purposes of simplicity those embodiments have not been specifically set forth in haec verba herein. Thus for each embodiment of the invention that comprises one or more elements, features, steps, etc., the invention also provides embodiments that consist or consist essentially of those elements, features, steps, etc.

Where ranges are given, endpoints are included. Furthermore, it is to be understood that unless otherwise indicated or otherwise evident from the context and/or the understanding of one of ordinary skill in the art, values that are expressed as ranges can assume any specific value within the stated ranges in different embodiments of the invention, to the tenth of the unit of the lower limit of the range, unless the context clearly dictates otherwise. It is also to be understood that unless otherwise indicated or otherwise evident from the context and/or the understanding of one of ordinary skill in the art, values expressed as ranges can assume any subrange within the given range, wherein the endpoints of the subrange are expressed to the same degree of accuracy as the tenth of the unit of the lower limit of the range.

In addition, it is to be understood that any particular embodiment of the present invention may be explicitly excluded from any one or more of the claims. Where ranges are given, any value within the range may explicitly be excluded from any one or more of the claims. Any embodiment, element, feature, application, or aspect of the compositions and/or methods of the invention, can be excluded from any one or more claims. For purposes of brevity, all of the embodiments in which one or more elements, features, purposes, or aspects is excluded are not set forth explicitly herein.

Tables

TABLE 1 CCR5-224 off-target sites in the genome of human K562 cells. Lower case letters indicate mutations compared to the target site. Sites marked with an ‘X’ were found in the corresponding in vitro selection dataset. ‘T’ refers to the total number of mutations in the site, and ‘(+)’ and ‘(−)’ to the number of mutations in the (+) and (−) half-sites, respectively. The sequences of the sites are listed as 5′ (+) half-site/spacer/(−) half-site 3′, therefore the (+) half-site is listed in the reverse sense as it is in the sequence profiles. K562 modification frequency is the frequency of observed sequences showing significant evidence of non-homologous end joining repair (see Methods) in cells expressing active ZFN compared to cells expressing empty vector. Sites that did not show statistically significant evidence of modifications are listed as not detected (n.d.), and K562 modification frequency is left blank for the three sites that were not analyzed due to non-specific PCR amplification from the genome. Table 4 shows the sequence counts and P-values for the tested sites used to determine K562 modification frequency, and Table 6 shows the modified sequences obtained for each site. in vitro (+) half-site (−) half-site selection K562 mutations (SEQ ID NOs: SEQ ID NOs: stringency (nM) modification T (+) (−) gene 190-226) spacer 227-263) 4 2  1 0.5 frequency  Full Sequence (SEQ ID NOs: 264-300) 0 0 0 CCR5 (coding) GTCATCCTCATC CTGAT AAACTGCAAAAG X X X X 1:2.3 2 1 1 CCR2 (coding) GTCgTCCTCATC TTAAT AAACTGCAAAAa X X X X 1:10 3 2 1 BTBD10 GTttTCCTCATC AAAGC AAACTGCAAAAt X X 1:1,400 (promoter) 4 0 4 GTCATCCTCATC AGAGA AAACTGgctAAt X X n.d. 4 3 1 SLC4A8 taaATCCTCATC TCTATA AAAaTGCAAAAG X X n.d. 3 2 1 Z83955 RNA GTCATCCcaATC GAAGAA AAACTGaAAAAG X X n.d. 3 1 2 DGKK cTCATCCTCATC CATGC AcAaTGCAAAAG X n.d. 3 1 2 GALNT13 GTCATCCTCAgC ATGGG AAACaGCAgAAG X n.d. 3 1 2 GTCATCtTCATC AAAAG gAACTGCAAAAc X 1:2,800 4 0 4 GTCATCCTCATC CAATA AAAgaaCAAAgG X n.d. 4 1 3 TACR3 GTCATCtTCATC AGCAT AAACTGtAAAgt X 1:300 4 1 3 PIWIL2 GTCATCCTCATa CATAA AAACTGCcttAG X 4 1 3 aTCATCCTCATC CATCC AAtgTtCAAAAG X n.d. 4 3 1 GTCcTgCTCAgC AAAAG AAACTGaAAAAG X 1:4,000 4 3 1 KCNB2 aTgtTCCTCATC TCCCG AAACTGCAAAtG X 1:1,400 4 3 1 GTCtTCCTgATg CTACC AAACTGgAAAAG X 1:5,300 4 3 1 aaCATCCaCATC ATGAA AAACTGCAAAAa X n.d. 6 3 3 aTCtTCCTCATt ACAGG AAAaTGtAAtAG X n.d. 6 4 2 CUBN GgCtTCCTgAcC CACGG AAACTGtAAAtG X 6 5 1 NID1 GTttTgCaCATt TCAAT tAACTGCAAAAG X n.d. 3 2 1 GTCAaCCTCAaC ACCTAC AgACTGCAAAAG X 1:1,700 4 1 3 WWOX GTCATCCTCcTC CAACTC cAAtTGCtAAAG X n.d. 4 2 2 AMBRA1 GTCtTCCTCcTC TGCACA tcACTGCAAAAG X n.d. 4 2 2 GTgATaCTCATC ATCAGC AAtCTGCAtAAG X n.d. 4 2 2 WBSCR17 GTtATCCTCAgC AAACTA AAACTGgAAcAG X 1:860 4 2 2 ITSN cTCATgCTCATC ATTTGT tAACTGCAAAAt X n.d. 4 4 0 GcCAgtCTCAgC ATGGTG AAACTGCAAAAG X n.d. 4 4 0 cTCATtCTgtTC ATGAAA AAACTGCAAAAG X n.d. 5 3 2 GaagTCCTCATC CCGAAG AAACTGaAAgAG X n.d. 5 3 2 ZNF462 GTCtTCCTCtTt CACATA AAACcGCAAAtG X n.d. 5 4 1 aTaATCCTttTC TGTTTA AAACaGCAAAAG X n.d. 5 4 1 GaCATCCaaATt ACATGG AAACTGaAAAAG X n.d. 5 5 0 SDK1 GTCtTgCTgtTg CACCTC AAACTGCAAAAG X n.d. 4 1 3 SPTB(coding) GTCATCCgCATC GCCCTG gAACTGgAAAAa X n.d. 4 2 2 aTCATCCTCAaC AAACTA AAACaGgAAAAG X 4 4 0 KIAA1680 GgaATgCcCATC ACCACA AAACTGCAAAAG X n.d. 5 5 0 GTttTgCTCcTg TACTTC AAACTGCAAAAG X n.d.

TABLE 2 Sequencing statistics. The total number of interpretable sequences (“total sequences”) and the number of analyzed sequences for each in vitro selection condition are shown. Analyzed sequences are non-repeated sequences containing no ambiguous nucleotides that, for post-selection sequences, contained reverse complementary overhang sequences of at least four bases, a signature used in this study as a hallmark of ZFN- mediated cleavage. “Incompatible overhangs” refer to sequences that did not contain reverse complementary overhang sequences of at least four bases. The high abundance of repeated sequences in the 0.5 nM, 1 nM, and 2 nM selections indicate that the number of sequencing reads obtained in those selections, before repeat sequences were removed, was larger than the number of individual DNA sequences that survived all experimental selection steps. Rejected Sequences Total Analyzed Incompatible Repeated Uncalled Bases in Sequences Sequences Overhangs Sequences Half-Sites CCR5-224 Pre- 1,426,442 1,392,578 0 33,660 206 Selection CCR5-224 0.5 nM 649,348 52,552 209,442 387,299 55 CCRS-224 1 nM 488,798 55,618 89,672 343,442 66 CCR5-224 2 nM 1,184,523 303,462 170,700 710,212 149 CCR5-224 4 nM 1,339,631 815,634 352,888 170,700 159 Total 5,088,742 2,619,842 822,702 1,645,563 635 VF2468 Pre-Selection 1,431,372 1,393,183 0 38,128 91 VF2468 0.5 nM 297,650 25,851 79,113 192,671 15 VF2468 1 nM 148,556 24,735 19,276 104,541 4 VF2466 2 nM 1,362,058 339,076 217,475 805,433 74 VF2468 4 nM 1,055,972 397,573 376,364 261,991 44 Total 4,295,608 2,180,388 692,228 1,422,764 228

TABLE 3 Both ZFNs tested have the ability to cleave a large fraction of target sites with three or fewer mutations. The percentage of the set of sequences with 1, 2, or 3 mutations (muts) that can be cleaved by (a) the CCR5-224 ZFN and (b) the VF2468 ZFN is shown. Enrichment factors (EFs) were calculated for each sequence identified in the selection by dividing the observed frequency of that sequence in the post-selection sequenced library by the observed frequency of that sequence in the preselection library. The enrichment factors for the wild-type sequence (wt EFs) calculated for each in vitro selection stringency are shown in the first row of the table. a CCR5-224 4 nM (wt EF = 5.48) 2 nM (wt EF = 8.11) 1 nM (wt EF = 16.6) 0.5 nM (wt EF = 24.9) 1 mut 2 muts 3 muts 1 mut 2 muts 3 muts 1 mut 2 muts 3 muts 1 mut 2 muts 3 muts EF > 0 100% 99.96% 78% 100% 99% 49% 100% 83% 14% 100% 75% 11% EF > 1 100%   93% 55% 100% 84% 42% 100% 68% 14% 100% 58% 11% EF > 2 100%   78% 37% 100% 70% 31%  99% 55% 14%  96% 46% 11% EF > (.5 × wt EF) 100%   63% 28%  93% 40% 17%  51% 15%  8%  31%  8%  4% EF > wt EF  14%    9% 10%  8%  6%  6%  3%  2%  3%  6%  1%  2% b VF2468 4 nM (wt EF = 16.7) 2 nM (wt EF = 22.5) 1 nM (wt EF = 30.2) 0.5 nM (wt EF = 33.1) 1 mut 2 muts 3 muts 1 mut 2 muts 3 muts 1 mut 2 muts 3 muts 1 mut 2 muts 3 muts EF > 0 100% 95% 38% 100% 92%  26% 100% 47%   5% 100% 44%   4% EF > 1  96% 49% 17%  93% 34%  11%  83% 24%   5%  80% 21%   4% EF > 2  69% 31% 10%  83% 23%   7%  74% 17%   5%  61% 14%   4% EF > (.5 × wt EF)  57% 15%  4%  30% 10%   2%  11%  6%   1%  9%  5%   1% EF > wt EF  7%  1%  1%  7%  1% 0.4%  7%  1% 0.4%  7%  1% 0.3%

TABLE 4 Potential CCR5-224 genomic off-target sites. The human genome was searched for DNA sequences surviving in vitro selection for CCR5-224 cleavage. Sites marked with an ‘X’ were found in the in vitro selection dataset. ‘T’ refers to the total number of mutations in the site, and ‘(+)’ and ‘(−)’ to the number of mutations in the (+) and (−) half-sites, respectively. Chromosomal coordinates from build 36 of the human genome are listed. Mutation frequency for each site is the percentage of sequences with insertions or deletions (indels) in the sequenced DNA from cultured K562 cells expressing active CCR5-224. Bolded red sites have significantly enriched indel percentages in the active nuclease sample compared to cells containing empty vector. The sequences of the sites are listed as 5′ (+) half site/spacer/(−) half-site 3′, therefore the (+) half-site is listed in the reverse sense as it is in the sequence profiles. Three sites were not tested since they did not yield site-specific PCR amplification products. Indels and totals are not shown for those sites that were not tested. P-values shown are for the one-sided alternative hypothesis that the indel frequency is greater for active ZFN treated cells than for cells not expressing ZFN. mutations T  (+) (−) gene build 36 coordinates (+) half-site spacer (−) half-site CCR5-224 1 0 0 0 CCR5 (coding) chr3: 46389548-46389576 GTCATCCTCATC CTGAT AAACTGCAAAAG CCR5-224 2 2 1 1 CCR2 (coding) chr3: 46374209-46374237 GTCgTCCTCATC TTAAT AAACTGCAAAAa CCR5-224 3 3 2 1 BTBD10 (promoter) chr11: 13441738-13441766 GTttTCCTCATC AAAGC AAACTGCAAAAt CCR5-224 4 4 0 4 chr10: 29604352-29604380 GTCATCCTCATC AGAGA AAACTGgctAAt CCR5-224 5 4 3 1 SLC4A8 chr12: 50186653-50186882 ttaaATCCTCATC TCTATA AAAaTGCAAAAG CCR5-224 6 3 2 1 Z83955 RNA chr12: 33484433-33484462 GTCATCCcaATC GAAGAA AAACTGaAAAAG CCR5-224 7 3 1 2 DGKK chrX: 50149961-50149989 cTCATCCTCATC CATGC AcAaTGCAAAAG CCR5-224 8 3 1 2 GALNT13 chr2: 154567664-154567692 GTCATCCTCAgC ATGGG AAACaGCAgAAG CCR5-224 9 3 1 2 chr17: 61624429-61624457 GTCATCtTCATC AAAAG gAACTGCAAAAc CCR5-224 10 4 0 4 chrX: 145275453-145275481 GTCATCCTCATC CAATA AAAgaaCAAAgG CCR5-224 11 4 1 3 TACR3 chr4: 104775175-104775203 GTCATCtTCATC AGCAT AAACTGtAAAgt CCR5-224 12 4 1 3 PIWIL2 chr8: 22191670-22191698 GTCATCCTCATa CATAA AAACTGCcttAG CCR5-224 13 4 1 3 chr9: 76194351-76194379 aTCATCCTCATC CATCC AAtgTtCAAAAG CCR5-224 14 4 3 1 chr8: 52114315-52114343 GTCcTgCTCAgC AAAAG AAACTGaAAAAG CCR5-224 15 4 3 1 KCNB2 chr8: 73389370-73898298 aTgtTCCTCATC TCCCG AAACTGCAAAtG CCR5-224 16 4 3 1 chr8: 4865886-4865914 GTCtTCCTgATg CTACC AAACTGgAAAAG CCR5-224 17 4 3 1 chr9: 14931072-14931100 aaCATCCaCATC ATGAA AAACTGCAAAAa CCR5-224 18 6 3 3 chr13: 65537258-65537286 aTCtTCCTCATt ACAGG AAAaTGtAAtAG CCR5-224 19 6 4 2 CUBN chr10: 17044849-17044877 GgCtTCCTgAcC CACGG AAACTGtAAAtG CCR5-224 20 6 5 1 NID1 chr1: 234244827-234244855 GTttTgCaCATt TCAAT tAACTGCAAAAG CCR5-224 21 3 2 1 chr9: 80584200-80584229 GTCAaCCTCAaC ACCTAC AgACTGCAAAAG CCR5-224 22 4 1 3 WWOX chr16: 77185306-77185335 GTCATCCTCcTC CAACTC cAAtTGCtAAAG CCR5-224 23 4 2 2 AMBRA1 chr11: 46422600-46422829 GTCtTCCTCcTC TGCACA tcACTGCAAAAG CCR5-224 24 4 2 2 chr1: 994566-16-99456645 GTgATaCTCATC ATCAGC AAtCTGCAtAAG CCR5-224 25 4 2 2 WBSCR17 chr7: 70557254-70557283 GTtATCCTCAgC AAACTA AAACTGgAAcAG CCR5-224 26 4 2 2 ITSN chr21: 34098210-34098239 cTCATgCTCATC ATTTGT tAACTGCAAAAt CCR5-224 27 4 4 0 chr9: 106457399-106457428 GcCAgtCTCAgC ATGGTG AAACTGCAAAAG CCR5-224 28 4 4 0 chr17: 49929141-49929170 CTCATtCTgtTC ATGAAA AAACTGCAAAAG CCR5-224 29 5 3 2 chr15: 96714952-96714981 GaagTCCTCATC CCGAAG AAACTGaAAgAG CCR5-224 30 5 3 2 ZNF462 chr9: 108684858-108684687 GTCtTCCTCtTt CACATA AAACcGCAAAtG CCR5-224 31 5 4 1 chr5: 101113644-101113673 aTaATCCTTtTC TGTTTA AAACaGCAAAAG CCR5-224 32 5 4 1 chr17: 43908810-43908839 GaCATCCaaATt ACATGG AAACTGaAAAAG CCR5-224 33 5 5 0 SDK1 chr7: 3446932-3446961 GTCtTgCTgTTg CACCTC AAACTGCAAAAG CCR5-224 34 4 1 3 SPTB(coding) chr14: 64329872-64329901 GTCATCCgCATC GCCCTG gAACTGgAAAAa CCR5-224 35 4 2 2 chr10: 54268729-54268758 aTCATCCTCAaC AAACTA AAACaGgAAAAG CCR5-224 36 4 4 0 KIAA1680 chr4: 92322851-92322880 GgaATgCcCATC ACCACA AAACTGCAAAAG CCR5-224 37 5 5 0 chr5: 114708142-114708171 GTttTgCTCcTg TACTTC AAACTGCAAAAG Table 4. Continued below; (+) half-sites SEQ ID NOs: 190-226 descending; (−) half sites SEQ ID NOs: 227-263 descending; full sequence with spacer descending SEQ ID NOs: 264-300. in vitro selection stringency empty vector active CCR5-224 4 nM 2 nM 1 nM  0.5 nM indels total mutation frequency indels total mutation frequency p-value X X X X 1 226676 0.00044% 105639 240968      44% 0 X X X X 0 114904 12856 130488      10% 0 X X 1 293015 0.00035% 166 224000   0.070% 0 X X 2 297084 0.00067% 3 245078  0.0012% 0.26 X X 0 147246 0 138979 X X 0 147157 1 146283 0.00068% 0.16 X 0 316468 0 313981 X 0 136684 0 94657 X 0 178692 52 146525   0.035% 2.7E−13 X 0 296730 0 276961 X 0 273436 1045 308726    0.34% 0 X X 0 168244 1 171618 0.00058% 0.16 X 0 66317 35 136728   0.025% 1.6E−08 X 1 427161 0.00023% 260 393899   0.071% 0 X 0 190993 32 171160   0.019% 7.7E−08 X 0 163704 0 146176 X 0 109939 0 100948 X X 0 114743 0 120169 X 0 188149 127 213248   0.060% 0 X 0 366156 0 354878 X 0 237240 0 227568 X 0 129468 0 144274 X 0 172543 488 417198    0.12% 0 X 0 267772 0 308093 X 0 350592 0 335281 X 0 105012 0 99968 X 0 355674 0 338910 X 0 173646 1 152744 0.00065% 0.16 X 1 245650 0.00041% 0 185572 0.84 X 0 482635 2 413317 0.00048% 0.079 X 0 237791 0 200398 X 0 180783 0 167885 X X 0 165657 2 153995  0.0013% 0.079 X 0 152083 0 183305

TABLE 5 There are many more potential genomic VF2468 target sites than CCR5-224 target sites. The human genome was computationally searched for sites up to nine mutations away from the canonical CCR5-224 target site and up to six mutations away from the canonical VF2468 target site. The number of occurrences of sites containing five or six base pair spacers in the genome, including repeated sequences, is listed in the table. CCR5-224 VF2468 # of site in # of sites in # of mutations genome # of mutations genome 0 1 0 1 1 0 1 3 2 1 2 245 3 6 3 3,201 4 99 4 35,995 5 964 5 316,213 6 9,671 6 2,025,878 7 65,449 8 372,801 9 1,854,317

TABLE 6 Sequences of CCR5-224-mediated genomic DNA modifications identified in cultured human K562 cells (SEQ ID NOs: 301-365, descending, then left to right). Sequences with insertions (blue) and deletions (red) identified after sequencing potential CCR5-224 off- target sites from cultured K562 cells expressing CCR5-224 are shown. The numbers of occurrences are shown to the right of each sequence. Other mutations are indicated with lowercase letters and likely reflect mutations that arose during PCR or sequencing. The unmodified site is listed under the gene name or coordinates (build 36), and the spacer sequence is underlined. # of sequences # of sequences BTBD10 (promoter) chr6: 52114315-52114343 ATTTTGCAGTTT GCTTT GATGAGGAAAAC CTTTTTCAGTTT CTTTT GCTGAGCAGGAC ATTTTGCAGTTT GCTTT GATGAGGAAAAC 63 CTTTTTCAGTTT CTTTT GCTGAGCAGGAC 35 ATTTTGCAGTTT GCTTTGCTTT GATGAGGAAAAC 86 ATTTTGCAGTTT GcTTTGCTTT GATGAGGAAAAC 1 ATTTTGCAGTTT GCTTTGCTTT GgTGAGGAAAAC 1 KCNB2 gTTTTGCAGTTT GCTTTGCTTT GATGAGGAAAAC 1 CATTTGCAGTTT CGGGA GATGAGGAACAT CTTTTGCAGgTT GCTTTGCTTT GATGAGGAAAAC 1 ATTTTGCAGTTT GCTTTGCTTT GATGtGGAAAAC 1 CATTTGCAGTTT CGGGAGA GATGAGGAACAT 158 ATTTTGCAGTTT GCTTT GATGAGGAAAAC 1 CATTTGCAGTTa CGGGAGA GATGAGGAACAT 1 CATTTGCAGTTT CGGGAGA GATGAGGgACAT 1 CATTTGacGcTT CGGGAGA GgTGAGGgACAT 1 chr17: 61824429-51624457 CATTTGCAGTTT CGGGCGGGA GATGAGGAACAT 109 GTTTTGCAGTTC CTTTT GATGAAGATGAC CATTTGCAGTTT CGGGCGGGA GATGcGGAACAT 1 CATTTGCAGTTT CGGGCGGGc GATGAGGAACAT 1 GTTTTGCAGTTC CTTTT GATGAAGATGAC 51 CATTTGCAGTTT CGGGCGGGA GgTGAGGAACAT 1 GTTTTGCAGgTC CTTTT GATGAAGATGAC 1 CgTTTGCAGTTT CGGGCGGGA GATGAGGAACAT 2 CATTTGCtGTTT CGGGCGGGA GATGAGGAACAT 1 CATTTGCAGTTT CGGGCGGGA GATGAGGAcCAT 1 TACR3 CATTTGCAGTTT CGGGCGGGA GATGAGGAcCAT 1 ACTTTACAGTTT ATGCT GATGAAGATGAC CcTTTGCAGTTT CGGGCGGGA GATGAGGAACAT 1 CATTTGCAGTTg CGGGCGGGA GATGAGGAACAT 1 ACTTTACAGTTT ATGCT GATGAAGATGAC 5 ACTTTACAGTTT ATGCT GATGAAGATGAC 169 gCTTTACAGTTT ATGCT GATGAAGATGAC 1 chr8: 4865886-4865914 ACTTTACAGTTT ATGCT GATGAAGATtAC 1 GTCTTCCTGATG CTACC AAACTGGAAAAG ACTTTACAGTTT ATGCT GATGAAGATGAtt 1 ACTTTACAGTTT ATGCT GATGAAGATGAC 34 GTCTTCCTGATG CTACC AAACTGGAAAAG 30 ACTTTACgGTTT ATGCT GATGAAGATGAC 1 GTCTTCCTGATG CTACC AAACTtGAAAAG 1 ACTTTACAGTTT ATGCT GATGAAGATGAC 180 GTCTTCaTGATG CTACC AAACTGGAAAAG 1 ACTTTACAGTTT ATGCT GATGAAGATGcC 1 ACTTTACAGTTT ATGCTATGCT GATGAAGATGAC 507 gCTTTACAGTTT ATGCTATGCT GATGAAGATGAC 1 chr9: 80584200-80584229 ACTTTACgGTTT ATGCTATGCT GATGAAGATGAC 1 CTTTTGCAGTCT GTAGGT GTTGAGGTTGAC ACTTTACAGTTT ATGCTATGCT GATGAtGATGAC 1 ACgTTACAGTTT ATGCTATGCT GATGAAGATGAC 1 CTTTTGCAGTCT GTAGGT GTTGAGGTTGAC 125 ACTTTACAGTTT ATGCT GATGAAGATGAC 140 CTTTTGCAGTCT GTAGGT GTTGAGGTTGAC 1 ACTTTACAGTTT ATGCT GATGAAGATGtC 1 CTTTTGCAGTCT GTAGGT GTTGAGGTTGAC 1 WBSCR17 GTTATCCTCAGC AAACTA AAACTGGAACAG GTTATCCTCAGC AAACTA ACTA AAACTGGAACAG 128 GTTATCCTCAGC AAACTA AAACTGGAACAG 118 GTTATCCTCAGC AAACTA AAACTGGgACAG 1 GTTATCCTCAGC AAACTA AAACTGGAcCAG 1 GTTATaCTCAGC AAACTA AAACTGGAACAG 1 GTTATCCTCAGC AAACTA AAACTGGAACAG 116 aTTATCCTCAGC AAACTA AAACTGGAACAG 1 GTTATCCTtAGC AAACTA AAACTGGAACAG 1 GTTATCCTCAGC AAACTA AAACTGGAACAG 116 GaTATCCTCAGC AAACTA AAACTGGAACAG 1 (Table 6 is presented as follows in four sections). Table 6—section one of four:

TABLE 7  Potential VF2468 genomic off-target sites. DNA for 90 out of 97 potential VF2468 genomic target sites were amplifiedby PCR from cultured K562 cells expressing active VF2468ZFN or from cells containingempty expression vector(SEQ ID NOs: 366-653). Mutation frequency for each site is the percentage of sequenceswith insertions or deletions (indels) in the sequenced DNA from cultured K562 cells expressing active VF2468.  mutations (+) (−) T (+) (−) gene buld 36 coordinates half-site spacer half-site VF2468 1 0 0 0 VEGF-A (promoter) chr8: 43,846,383-43,845,415 AGCAGCGTC TTCGA GAGTGAGGA VF2468 2 1 0 1 chr1: 158,832,650-1468,832,672 AGCAGCGTC AATAC GAGTGAaGA VF2468 3 1 1 0 chr1: 242,574,122-242,574,144 AGCAGCcTC TGCTT GAGTGAGGA VF2468 4 1 1 0 ZNF683 chr1: 26,569,668-26,869,690 AGCAGCGTt GGGAG GAGTGAGGA VF2468 5 2 0 2 GSG1L chr16: 27,853984-27,854,006 AGCAGCGTC AAAAA cAGTGAGcA VF2468 6 2 0 2 C9orf98 chr9: 134,636,934-134,696,956 AGCAGCGTC GTGTG GtGTGAGGt VF2468 7 2 0 2 EFHD1 chr2: 233,205,384-233,205,407 AGCAGCGTC GTTCTC aAGTGgGGA VF2468 8 2 0 2 chr20: 30,234,845-30,234,868 AGCAGCGTC TAGGCA GAGaGAaGA VF2468 9 2 0 2 KIAA0841 (exon-Intron) chr19: 40,800,787-40,800,820 AGCAGCGTC TAGGGG GAGgGAGGg VF2468 10 2 0 2 CES7 chr16: 54,501,918-54,501,940 AGCAGCGTC TCAAAA GAGTGtGcA VF2468 11 2 0 2 PTK2B chr8: 27,338,855-27,338,878 AGCAGCGTC TCCCTT GAGTGAtGg VF2468 12 2 0 2 chr9: 137,315,499-137,315,521 AGCAGCGTC TGAAA GAGTGAaaA VF2468 13 2 1 1 chr20: 7,985,741-7,985,493 AGaAGCGTC ATCGA GAGTGAGGt VF2468 14 2 1 1 chrY: 8,461,018-8,451,041 AGCAaCGTC AGATAG GgGTGAGGA VF2468 15 2 1 1 chr1: 53,720,668-53,720,690 AGCAaCGTC ATATT cAGTGAGGA VF2468 16 2 1 1 chrX: 122,132,519-122,132,541 AGCAaCGTC GTAGT GAtTGAGGA VF2468 17 2 1 1 F4HA1 chr10: 4,506,346-74,506,368 AGCAcCGTC TTTTC tAGTGAGGA VF2468 18 2 1 1 DFKZp686L07201 chrX: 56,830,910-56,830,933 AGCAGaGTC AGACTT GAGTGAGGt VF2468 19 2 1 1 TTC4 chr1: 54,881,895-54,881,917 AGCAGaGTC TCTGA GAGTGAGGc VF2468 20 2 1 1 chr1: 175,647,668-175,647,690 AGCAGCaTC AGTGA GAGTGAGGc VF2468 21 2 1 1 chr1: 50,490,333-50,490,356 AGCAGCcTC TCCAAA GAGTGAGGc VF2468 22 2 1 1 chr4: 128,224,847-128,224,870 AGCAGCcTC TGCATC GAGTGAGGt VF2468 23 2 1 1 chr13: 27,399,187-27,399,210 AGCAGCGaC GCCTGG GAGTGAGGt VF2468 24 2 1 1 chr16: 62,603,303-62,603,326 AGCAGCGTa TCACAT GAGTGAGGg VF2468 25 2 1 1 chr11: 69,063,501-69,063,523 AGCAGCGTg CCCAA GAGTGAGGc VF2468 26 2 1 1 TNR chr1: 173,885,442-173,885,465 AGCAGCtTC AGGGGGA GtGTGAGGA VF2468 27 2 1 1 PTPRM chr18: 8,320,310-8,320,332 AGCAGCtTC CTTTT GAGTGAGaA VF2468 28 2 1 1 chr12: 25,724,566-25,724,589 AGCAGCtTC TCCTGG GAGTGAGGg VF2468 29 2 1 1 chr13: 82,039,140-82,039,163 AGCAGgGTC AGGGCT GAGTGAGGc VF2468 30 2 1 1 chr3: 131,201,895-131,201,918 AGCAGtGTC AGGCTG GtGTGAGGA VF2468 31 2 1 1 chr3: 75,709,387-75,709,410 AGCAGtGTC AGGCTG GtGTGAGGA VF2468 32 2 1 1 chr11: 3,556,299-3,556,332 AGCAGtGTC AGGCTG GtGTGAGGA VF2468 33 2 1 1 chr3: 126,970,762-126,970,785 AGCAGtGTC AGGCTG GtGTGAGGA VF2468 34 2 1 1 chr11: 71,030,884-71,030,907 AGCAGtGTC AGGCTG GtGTGAGGA VF2468 35 2 1 1 SBF2/U80769 chr11: 9,884,211-9,884,234 AGCAGtGTC CTAAGG GgGTGAGGA VF2468 36 2 1 1 KRI1 (coding) chr19: 10,534,492-10,534,515 AGCAtCGTC ATCAGA cAGTGAGGA VF2468 37 2 1 1 chr6: 112,421,476-112,421,499 AGCAtCGTC TGAAGT GAGTGAGGc VF2468 38 2 1 1 MICAL3/KIAA1364 chr22: 16,718,914-16,718,937 AGCAtCGTC TTCTGT GAGTGAGtA VF2468 39 2 1 1 MUC16 (exon-Intron) chr19: 8,894,218-8,894,241 AGgAGCGTC TCACCT GAGTGAGGc VF2468 40 2 2 0 chr8: 5,638,000-6,638,023 AaCAGCtTC ATCTCG GAGTGAGGA VF2468 41 2 2 0 PREX1 chr20: 46,733,644-46,733,667 AaCAGCtTC TCGGGA GAGTGAGGA VF2468 42 2 2 0 CDH20 chr18: 57,303,454-57,303,477  AaCAGCtTC TCTGAG GAGTGAGGA VF2468 43 2 2 0 chr20: 6,213,500-6,213,522 AGCAaaGTC AAACA GAGTGAGGA VF2468 44 2 2 0 chr5: 85,841,308-85,841,331 AGCAaCtTC TGGAAA GAGTGAGGA VF2468 45 2 2 0 chr8: 20,481,270-20,481,292 AGCAcCtTC AATTG GAGTGAGGA VF2468 46 2 2 0 chr5: 95,417,045-95,417,068 ACAGCaTa ATAGCA GAGTGAGGA VF2468 47 2 2 0 RORA chr15: 59,165,302-59,165,325 ACAGCaTa GATATG GAGTGAGGA VF2468 48 2 2 0 chr6: 24,504,489-24,504,511 ACAGCaTa TCAGG GAGTGAGGA VF2468 49 2 2 0 chr3: 31,085,287-31,085,309 AGCAGCGag AAAGA GAGTGAGGA VF2468 50 2 2 0 chr6: 27,579,690-27,579,712 AGCAGCGgt CTTAG GAGTGAGGA VF2468 51 2 2 0 chr12: 113,410,592-113,410,615 AGCAGgGTt CTTCAA GAGTGAGGA VF2468 52 2 2 0 chr1: 11,399,534-11,399,556 AGCtGaGTC CTAAA GAGTGAGGA VF2468 53 2 2 0 MCTP1 chr5: 94,590,016-94,590,038 AGCtGaGTC TTAAG GAGTGAGGA VF2468 54 2 2 0 chr1: 13,394,902-13,394,924 AGCtGgGTC ATGAG GAGTGAGGA VF2468 55 2 2 0 PRAMEF20 chr1: 13,615,741-13,615,763 AGCtGgGTC ATGAG GAGTGAGGA VF2468 56 2 2 0 chr20: 59,154,784-59,154,806 AGCtGtGTC CACAG GAGTGAGGA VF2468 57 2 2 0 chr14: 100,903,675-100,903,697 AGCtGtGTC TTGGA GAGTGAGGA VF2468 58 2 2 0 chrX: 141,701,170-141,701,192 AGtAGCGgC AAATT GAGTGAGGA VF2468 59 2 2 0 GTF3C1 chr15: 27,452,953-27,452,975 AGtgGCGTC CCAGT GAGTGAGGA VF2468 60 2 2 0 DNMBP/AK089111 chr10: 101,688,961-101,688,983 gGCAGaGTC CTAGA GAGTGAGGA VF2468 61 2 2 0 chr6: 137,852,455-137,852,478 tcCAGCGTC CTCCCA GAGTGAGGA VF2468 62 2 2 0 SARDH chr9: 135,592,239-135,592,262 tGCAGCGgC GTAGGG GAGTGAGGA VF2468 63 2 2 0 chr7: 19,683,400-19,683,423 tGCAGCGTt AAAATA GAGTGAGGA VF2468 64 2 2 0 ZNF628 chr19: 60,683,246-60,683,269 tGCAGgGTC GGGCAG GAGTGAGGA VF2468 65 2 2 0 chr3: 130,430,426-130,430,448 tGCAGtGTC CACAA GAGTGAGGA VF2468 66 3 1 2 GBF1 chr10: 104,073,989-104,074,012 AGCAaCGTC CATAGT GtGTGAGaA VF2468 67 3 1 2 chr14: 96,561,728-96,561,751 AGCAaCGTC TAACCC GAGTGttGA VF2468 68 3 1 2 PDE9A chr21: 42,982,083-42,982,105 AGCAcCGTC CCCCT cAGTGAGGc VF2468 69 3 1 2 MTX2 chr2: 176,842,448-176,842,470 AGCAGCGgC GGCTG cAGTGAGGc VF2468 70 3 1 2 chr6: 104,071,040-104,071,063 AGCAGCGgC TTAAGG GgGTGAGGt VF2468 71 3 1 2 chr3: 32,220,862-32,220,885 AGCAGtGTC TAAAAG GAGTGAGat VF2468 72 3 2 1 chr2: 11,429,195-11,429,218 AGaAaCGTC GTGGAG GAGTGAGGg VF2468 73 3 2 1 OPN5 chr6: 47,891,415-47,891,438 AGCAaaGTC TGTACT GAGTGAGGg VF2468 74 3 2 1 chr2: 195,362,417-195,362,439 AGCAaCaTC ATCTT GAGTGAGGg VF2468 75 3 2 1 MIPOL1 chr14: 36,952,701-36,952,724 AGCAaCaTC TGGTTG GAGTGAGGg VF2468 76 3 2 1 chr4: 138,603,959-138,603,981 AGCAaCtTC ATCTT GAGTGAGGg VF2468 77 3 2 1 LRCH1 chr13: 46,079,921-46,079,943 AGCAaCtTC CTGGC GAGTGAGGg VF2468 78 3 2 1 KIAA0999 chr11: 116,292,384-116,292,406 AGCAatGTC AAAAA GAGTGAGGc VF2468 79 3 2 1 chr12: 13,353,629-13,353,651 AGCAcCGTg GCTTC GAGTGAGGc VF2468 80 3 2 1 PLXNA4 (coding) chr7: 131,503,708-131,503,730 AGCAcgGTC ATGAT GAGTGAGGc VF2468 81 3 2 1 TSPEAR chr21: 44,817,259-44,817,282 AGCAGCagC CCACAG GAGTGAGGg VF2468 82 3 2 1 chr18: 74,634,790-74,634,812 AGCAGCagC TAGGG GAGTGAGGg VF2468 83 3 2 1 chr10: 33,904,306-33,904,328 AGCAGCtcC TCTCC GAGTGAGGt VF2468 84 3 2 1 chr6: 170,226,156-170,226,178 AGCAGgGTg GCGTG GAGTGAGGc VF2468 85 3 2 1 chr3: 118,594,878-118,594,901 AGCAtaGTC TAGGCC GAGTGAGGc VF2468 86 3 2 1 HRASLS chr3: 194,452,125-194,452,147 AGCAtgGTC CCAAG GAGTGAGGg VF2468 87 3 2 1 chr17: 19,434,508-19,434,531 AGCAttGTC TCATGT GAGTGAGGt VF2468 88 3 2 1 chr8: 125,982,579-125,982,601 AGCAttGTC TCCTG GAGTGAGGg VF2468 89 3 2 1 UHRF1BP1L chr12: 99,011,715-99,011,737  AGtAGCGTt TTTAG GAGTGAGGt VF2468 90 3 2 1 chr1: 14,762,405-14,762,427 AtCAGaGTC TCTGG GAGTGAGGc VF2468 91 3 2 1 LAMB3 (promoter) chr1: 207,894,359-,207,894,382 AtCAGtGTC CCTCAG GAGTGAGGc VF2468 92 3 2 1 BRUNOL4 chr18: 33,160,009-33,160,032 gGCAGaGTC AGGGCT GAGTGAGGc VF2468 93 3 2 1 chr16: 84,004,297-84,004,320 gGCAGCGgC CGCTGT GAGTGAGGt VF2468 94 3 2 1 DFKZp586E1619/BRD chr22: 48,558,064-48,558,086 tGCAGCtTC ATGGT GAGTGAGGc VF2468 95 3 3 0 chr7: 22,054,784-22,054,807 AGCAtaGTt ACCTGG GAGTGAGGA VF2468 96 3 3 0 chr14: 25,876,126-25,876,149 AGtAaaGTC TAAGTA GAGTGAGGA VF2468 97 4 3 1 CNNM2 chr10: 104716,593-104,716,615 tGCAGtcTC CTTGG GAGTGAGGt In vitro  empty vector active VF2468 selection stringency mutation mutation 4 nM 2 nM 1 nM 0.5 nM indels total frequency indels total frequency p-value VF2468 1 X X X X 126 147187 0.085% 27067 186785 14% 0 VF2468 2 X X X X 0 57855 1 62195 0.0016% 0.16 VF2468 3 X X X X 0 167447 0 147340 VF2468 4 X X X X 0 111340 0 109365 VF2468 5 X X X X 0 80047 0 69080 VF2468 6 X X X X VF2468 7 X X X X 0 202694 0 204809 VF2468 8 X X X X 0 160769 1 158886 0.00063% 0.16 VF2468 9 X X X X 1 81164 0.0012% 445 79136 0.56% 0 VF2468 10 X X X X 1 168501 0.00059% 0 144701 0.84 VF2468 11 X X X X 0 179502 56 138649 0.040% 3.6E−14 VF2468 12 X X X X 0 285530 165 254714 0.065% 0 VF2468 13 X X X X 0 166914 0 148547 VF2468 14 X X X X VF2468 15 X X X X 0 329599 145 290700 0.050% 0 VF2468 16 X X X X 0 157651 0 136373 VF2468 17 X X X X VF2468 18 X X X X 0 13660 13 12386 0.10% 0.00015 VF2468 19 X X X X 0 176808 163 191327 0.085% 0 VF2468 20 X X X X 1 286818 0.00035% 3 343497 0.00087% 0.20 VF2468 21 X X X X 0 168032 0 183289 VF2468 22 X X X X 0 86347 0 87663 VF2468 23 X X X X 0 23198 394 34456 1.1% 0 VF2468 24 X X X X 0 57001 283 63841 0.44% 0 VF2468 25 X X X X 0 181022 0 221989 VF2468 26 X X X X 0 132693 0 139071 VF2468 27 X X X X 0 73084 0 100249 VF2468 28 X X X X 0 323231 1116 353441 0.32% 0 VF2468 29 X X X X 0 156241 439 168937 0.26% 0 VF2468 30 X X X X 0 77427 1960 92791 2.1% 0 VF2468 31 X X X X 0 34408 114 33070 0.34% 0 VF2468 32 X X X X 0 19630 18 17409 0.11% 6.5E−08 VF2468 33 X X X X 0 89679 2670 90901 2.8% 0 VF2468 34 X X X X 0 112449 231 150275 0.15% 0 VF2468 35 X X X X 0 418083 695 532165 0.13% 0 VF2468 36 X X X X 0 141739 0 139368 VF2468 37 X X X X 0 153897 1174 178559 0.66% 0 VF2468 38 X X X X 0 287706 175 283788 0.062% 0 VF2468 39 X X X X 0 212038 0 219913 VF2468 40 X X X X 0 132803 0 147070 VF2468 41 X X X X 0 204408 0 227091 VF2468 42 X X X X 1 313747 0.00032% 1 403382 0.00025% 0.57 VF2468 43 X X X X 1 154154 0.00065% 0 193644 0.84 VF2468 44 X X X X VF2468 45 X X X X 0 250890 0 237104 VF2468 46 X X X X 0 247702 1 319493 0.00031% 0.15 VF2468 47 X X X X 0 270263 1 358704 0.00028% 0.15 VF2468 48 X X X X 0 103878 0 176333 VF2468 49 X X X X 0 542052 0 708517 VF2468 50 X X X X 0 177732 1 212250 0.00047% 0.15 VF2468 51 X X X X 0 294783 0 302167 VF2468 52 X X X X 0 482765 1 402831 0.00025% 0.15 VF2468 53 X X X X 0 183510 1 202083 0.00049% 0.15 VF2468 54 X X X X 0 88944 0 105879 VF2468 55 X X X X VF2468 56 X X X X 0 360710 0 351215 VF2468 57 X X X X 0 140671 0 157922 VF2468 58 X X X X 0 196624 0 209781 VF2468 59 X X X X 0 223714 0 246196 VF2468 60 X X X X 0 302495 0 383303 VF2468 61 X X X X 0 84153 0 113996 VF2468 62 X X X X 0 191187 138 212085 0.065% 0 VF2468 63 X X X X 1 372808 0.00027% 2 438355 0.00046% 0.33 VF2468 64 X X X X 0 167551 0 185442 VF2468 65 X X X X VF2468 66 X X X X 4 545543 0.00073% 3756 587393 0.64% 0 VF2468 67 X X X X 0 171147 0 203860 VF2468 68 X X X X 0 89976 391 137236 0.28% 0 VF2468 69 X X X X 0 38342 153 50273 0.30% 0 VF2468 70 X X X X 0 252020 0 277262 VF2468 71 X X X X 0 178243 0 255921 VF2468 72 X X X X 0 138844 94 221676 0.042% 0 VF2468 73 X X X X 0 182565 2808 212729 1.3% 0 VF2468 74 X X X X 0 103739 1 130605 0.00077% 0.15 VF2468 75 X X X X 1 300572 0.00033% 0 355283 0.84 VF2468 76 X X X X 0 185773 0 185094 VF2468 77 X X X X 1 131239 0.00076% 0 133319 0.84 VF2468 78 X X X X 0 212883 243 157434 0.15% 0 VF2468 79 X X X X 0 112164 34 116695 0.029% 2.7E−09 VF2468 80 X X X X 0 195577 77 188335 0.041% 0 VF2468 81 X X X X 1 151845 0.00066% 0 144107 0.84 VF2468 82 X X X X VF2468 83 X X X X 0 240952 1 233954 0.00043% 0.16 VF2468 84 X X X X 0 191108 0 167663 VF2468 85 X X X X 0 405643 209 355997 0.059% 0 VF2468 86 X X X X 0 212942 393 247078 0.16% 0 VF2468 87 X X X X 0 4171 18 3024 0.60% 1.0E−05 VF2468 88 X X X X 0 115967 59 115268 0.051% 7.8E−15 VF2468 89 X X X X 1 171873 0.00058% 0 207336 0.84 VF2468 90 X X X X 2 193447 0.0010% 1 196665 0.00051% 0.72 VF2468 91 X X X X 0 107549 0 109933 VF2468 92 X X X X 0 71298 0 77229 VF2468 93 X X X X 0 99279 0 121284 VF2468 94 X X X X 0 152251 0 206428 VF2468 95 X X X X 0 91338 0 134004 VF2468 96 X X X X 0 245402 0 345728 VF2468 97 X X X X 0 76762 0 92742 Bolded red sites have significantly enriched indel percentages in the active nuclease sample compared to cells not expressing nuclease. The sequences of the sites are listed as 5′ (+) halfsite (SEQ ID NOs: 366-461)/spacer/(−) half-site 3′ (SEQ ID NOs: 462-557) (Full sequences are SEQ ID NOs: 558-653), therefore the (+) half-site is listed in the reverse sense as it is in the sequence profiles. Seven sites were not tested since they did not yield site-specific PCR amplification products. Indels and totals are not shown for those sites that were not tested. P-values shown are for the one-sided alternative hypothesis that the indel frequency is greater for active ZFN treated cells than for cells not expressing ZFN.

TABLE 8 Oligonucleotides used in this study. Oligonucleotides “[ZFN] [#] fwd/rev” were ordered from Invitrogen. All other oligonucleotides were ordered from Integrated DNA Technologies. ‘N’ refers to machine mixed incorporation of ‘A’, ‘C’, ‘G’, or ‘T.’ An asterisk indicates that the preceding nucleotide was incorporated as a mixture containing 79 mol % of that nucleotide and 7 mol % each of the other canonical nucleotides. “/5Phos/” denotes a 5′ phosphate group installed during synthesis. Sequences are listed as SEQ ID NOs: 654-924 descending. oligonucleotide name oligonucleotide sequence (5′->3′) N5-Pvul NNNNNCGATCGTTGGGAACCGGA CCR5-224-N4 NG*T*C*A*T*C*C*T*C*A*T*C*NNNNA*A*A*C*T*G*C*A*A*A*A*G*NCAGTGGAACGAA CCR5-224-IN5 NG*T*C*A*T*C*C*T*C*A*T*C*NNNNNA*A*A*C*T*G*C*A*A*A*A*G*NCAGTGGAACGAAAACTCACG CGR5-224-N6 NG*T*C*A*T*C*C*T*C*A*T*C*NNNNNNA*A*A*C*T*G*C*A*A*A*A*G*NCAGTGGAACGAAAACTCACG CCR5-224-N7 NG*T*C*A*T*C*C*T*C*A*T*C*NNNNNNNA*A*A*C*T*G*C*A*A*A*A*G*NCAGTGGAACGAAAACTCACG VF2468-N4 NA*G*C*A*G*C*G*T*C*NNNNG*A*G*T*G*A*G*G*A*NCAGTGGAACGAAAACTCACG VF2468-N5 NA*G*C*A*G*C*G*T*C*NNNNNG*A*G*T*G*A*G*G*A*NCAGTGGAACGAAAACTCACG VF2468-N6 NA*G*C*A*G*C*G*T*C*NNNNNNG*A*G*T*G*A*G*G*A*NCAGTGGAACGAAAACTCACG VF2468-N7 NA*G*C*A*G*C*G*T*C*NNNNNNNG*A*G*T*G*A*G*G*A*NCAGTGGAACGAAAACTCACG test fwd GCGACACGGAAATGTTGAATACTCAT test rev CAGCGAGTCAGTGAGCGA adapter1 ACACTCTTTCCCTACACGACGCTCTTCCGATCTT adapter1(AAT) ACACTCTTTCCCTACACGACGCTCTTCCGATCTAATT adapter1(ATA) ACACTCTTTCCCTACACGACGCTCTTCCGATCTATAT adapter1(TAA) ACACTCTTTCCCTACACGACGCTCTTCCGATCTTAAT adapter1(CAC) ACACTCTTTCCCTACACGACGCTCTTCCGATCTCACT adapter2 /5Phos/AGATCGGAAGAGCGGTTCAGCAGGAATGCCGAG adapter2(AAT) /5Phos/ATTAGATCGGAAGAGCGGTTCAGCAGGAATGCCGAG adapter2(ATA) /5Phos/TATAGATCGGAAGAGCGGTTCAGCAGGAATGCCGAG adapter2(TAA) /5Phos/TTAAGATCGGAAGAGCGGTTCAGCAGGAATGGCGAG adapter2(CAC) /5Phos/GTGAGATCGGAAGAGCGGTTCAGCAGGAATGCCGAG PE1 CAAGCAGAAGACGGCATACGAGATCGGTCTCGGCATTCCTGCTGAACCGCTCTTCCGATC PE2 AATGATACGGCGACCACCGAGATCTACACTCTTTCCCTACACGACGCTCTTCCGATCT CCR5-224 1 fwd ATACATCGGAGCCCTGCCAA CCR5-224 1 rev GGAAAAACAGGTCAGAGATGGC CCR5-224 2 fwd TCCTGCCTCCGCTCTACTCG CCR5-224 2 rev ACCCCAAAGGTGACCGTCCT CCR5-224 3 fwd TCCCSCGTTTTCCCCTTGAC CCR5-224 3 rev GTCCCTCACGACGACCGACT CCR5-224 4 fwd GCACTGCCCCAGAAATATTGGTT CCR5-224 4 rev TGGTTTGTTGGGGGATCAGG CCR5-224 5 fwd ATGCCACCCCTGCCAGATAA CCR5-224 5 rev GCCTACCTCAATGCAGGCAAA CCR5-224 6 fwd TCTGCTTCTGCCCTTGTGGA CCR5-224 6 rev GGAGGATCGCCAAGACCTGA CCR5-224 7 fwd CCCCAGTGCTTAAGATAGTTCTTGG CCR5-224 7 rev ACTCCCAGACAAACCCCGCT CCR5-224 8 fwd GGCACCAGAACTTACTCACTGCC CCR5-224 8 rev TGTGAAGGCCCAAAACCCTG CCR5-224 9 fwd GTTTTGGGGGTCATGGCAAA CCR5-224 9 rev TGGGCAGGCCCTAGGTCCTTT CCR5-224 10 fwd TTTCCCTGGTGATGCACTCCT CCR5-224 10 rev TGATGAGTAACTTGGGCGAAAA CCR5-224 11 fwd TTGGGGGAATGAGATTGGGA CCR5-224 11 rev GGAAAATCCAGCAAGGTGAAA CCR5-224 13 fwd CCTTCCCATGGTCACAGAGG CCR5-224 13 rev CAACTCTCTAACAGCAAAGTGGCA CCR5-224 14 fwd TCCTCCCGTTGAGGAAGCAC CCR5-224 14 rev GCCTCAAAAGCATAAACAGCA CCR5-224 15 fwd CAGACCGCTGGTGCTGAGAC CCR5-224 15 rev AGGGCGGACTCATTGCTTTG CCR5-224 16 fwd TGGGTTCCTCGGGTTCTCTG CCR5-224 16 rev GAAACCAGAAGTTCACAACAATGCTT CCR5-224 17 fwd AGGCATAAGCCACTGCACCC CCR5-224 17 rev TGGCAATGCCTAATCAGACCA CCR5-224 18 fwd GAGGATATTTTATTGCTGGCTCTTGC CCR5-224 18 rev GAGTTTGGGGAAAAGCCACTT CCR5-224 20 fwd GCTGAGGCCCACCTTTCCTT CCR5-224 28 rev TGCTCTGCCAACTGTGAGGG CCR5-224 21 fwd TGTTTTGGGTGCATGTGGGT CCR5-224 21 rev TCCAGGGAGTGAGGTGAAGACA CCR5-224 22 fwd CTGGGTCAGCTGGGCCATAC CCR5-224 22 rev TCACATCTCCGCCTCACGAT CCR5-224 23 fwd CCAGCCTTGGAAAAATGGACA CCR5-224 23 rev CTGACACAGTGGCCAGCAGC CCR5-224 24 fwd CATGGATGTAATGGGTTGTATCTGC CCR5-224 24 rev GAGGGCAGAAGGGGGTGAGT CCR5-224 25 fwd AGGATGCATTGTCCCCCAGA CCR5-224 25 rev TGGAGTGACATGTATGAAGCCA CCR5-224 26 fwd CGTTGGCTTGCAGAAGGGAC CCR5-224 26 rev TGAACCCCGGATTTTTCAACC CCR5-224 27 fwd TGACCCAACTAAGTCTGTGACCC CCR5-224 27 rev TTGGGAAAGCTTTGATGCTGG CCR5-224 28 fwd TGGGTTGTGTTTTTGACTGACAGA CCR5-224 28 rev CCCTAGGGGTCACTGGAGCA CCR5-224 29 fwd CACCCCCATGCAGGAAAATG CCR5-224 29 rev TTGGCTGCTGGCATTTGGTA CCR5-224 33 fwd GGCCATTGGTTCTGGAGGAA CCR5-224 30 rev TCCGTTGCTTCATCCTTCCAA CCR5-224 31 fwd AGTCAGCAATGCCCCAGAGC CCR5-224 31 rev TGGAGAGGGTTTACTTTCCCAGA CCR5-224 32 fwd CCTGGGAGGGTGACTAGTTGGA CCR5-224 32 rev GCTCAGGGCCTGGCTTACAG CCR5-224 33 fwd TGGCAATTAGGATGTGCCAG CCR5-224 33 rev TCCACTCACAAATTTACCTTTCCAC CCR5-224 34 fwd TGCGCCACATCTTCACCAGA CCR5-224 34 rev CCGCATAAAGGAGGTGTCGG CCR5-224 36 fwd GTTGCATCTGCGGTCTTCCA CCR5-224 36 rev GGAGAGTCTTCCGCCTGTGTT CCR5-224 37 fwd TAGTGGCCCCAACATGCAAA CCR5-224 37 rev GCACATATCATGCACTGTGACTGTAA VF2468 1 fwd CCTTTCCAAAGCCCATTCCC VF2468 1 rev CAACCCCACACGCACACAC VF2468 2 fwd TTCACTGCCTTCAGGCCTCC VF2468 2 rev AATGGCCAGAAAATTCCCAAA VF2468 3 fwd CACAGGGACCCAGGACTGCT VF2468 3 rev TGACTGGAACCGTGCAGCAT VF2468 4 fwd GCACCAGGCTTCTCTGCCAT VF2468 4 rev TCGGGGGTCCATGGTATTTG VF2468 5 fwd CCAAGGCGAGGACATTGAGG VF2468 5 rev CCCCAAGTCAGACCCTGCAT VF2468 7 fwd ACCATAGTCCAGCGGGGTCA VF2468 7 rev TTCTCCCCAAGGAAGGCTGA VF2468 8 fwd AGAAAGGGTGGTCGGGGAAG VF2468 8 rev GCCACCATGCCCAGTCTACA VF2468 9 fwd TTCCCATGGGGTCTCAGCTC VF2468 9 rev ATGGCCTTCCCCAACTGTGA VF2468 10 fwd CAGCAAGGATGCCGTTCACC VF2468 10 rev CGTTGTGATTGAGGAGACGAGG VF2468 11 fwd GGCTTGAGCTGGAAGGACCA VF2468 11 rev TGGAGCAACTGAACATGTTGGG VF2468 12 fwd AACCGAGTTTGCACCGTCGT VF2468 12 rev CATAACCACCAGGACATCCGC VF2468 13 fwd TATCCTCCCCTTTCCCCTGA VF2468 13 rev TGTTGCCAGAAGTATCAGGTCCC VF2468 15 fwd AGAACCCGGAATCCCTTTGC VF2468 15 rev GCAGAGAAGGCAGCAGCACA VF2468 16 fwd GGTCTCTGCCATGCCCAACT VF2468 16 rev TGGAGGAAGCAGGAAAGGCAT VF2468 18 fwd CCCCTTGGGATCCTTGTCCT VF2468 18 rev TCAACAGGCAGGTACAGGGC VF2468 19 fwd CTAGGCCTGTGGGCTGAGGA VF2468 19 rev CAAATGTTGGGGTGTGGGTG VF2468 20 fwd TACCTGAAACCCCTGGCCCT VF2468 20 rev CAAGCTGGATGTGGATGCAGAG VF2468 21 fwd CGGGGGCCTGACATTAGTGA VF2468 21 rev GCCTGAAGATGCATTTGCCC VF2468 22 fwd TGCATTGGCTCAAGAATTGGG VF2468 22 rev TCACACAGTGGTAATGGACAGGAA VF2468 23 fwd GCGCTCCCTGTGTTCAGTACC VF2468 23 rev GCGCAAGTTCCCCTTTCTGA VF2468 24 fwd TGTTTGGGTTATGGGGGCAG VF2468 24 rev TCCAGCATCTGCTCCTGGTG VF2468 25 fwd AAGGAGACTTCTCAGGCCCCA VF2468 25 rev TGAAGGGAAGCCACAGCTCC VF2468 26 fwd CTTGGGGGCAGACAGCATCT VF2468 26 rev GCCATGGGATGGCAGTTAGG VF2468 27 fwd TGGCCTCAAGCAATCCTCCT VF2468 27 rev TTCCATGGCAGTGAAGGGTG VF2468 28 fwd CCAAAGAGCCTGGAGGAGCA VF2468 28 rev CAGAGGGTGTGGTGGTGTCG VF2468 29 fwd CCAGCCTGTGAAGCTGGAAGTAA VF2468 29 rev CCAGTGGGCTGAGTGGATGA VF2468 30 fwd CATCTGAATGCCCATGCTGC VF2468 30 rev CCGCCACACCCATTCCTC VF2468 31 fwd CCTCAAAGAAACGGCTGCTGA VF2468 31 rev GCCGCTCGAAAAGAGGGAAT VF2468 32 fwd CGGGCTCTCCTCCTCAAAGA VF2468 32 rev GGCCCCTTGAAAAGAGGGAA VF2468 33 fwd GGAATCGCATGACCTGAGGC VF2468 33 rev CGGGCTCTCCTCCTCAAAGA VF2468 34 fwd CCCGCCAGACACATTCCTCT VF2468 34 rev CATCTGAATGCCCATGCTGC VF2468 35 fwd CCGCACCTTTTTCCTATGTGGT VF2468 35 rev TCAGATGTGGTAGGAGACAGATGAC VF2468 36 fwd GGTACATGGGCCGCACTTTC VF2468 36 rev GGACAGCTGGGAATTGGTGG VF2468 37 fwd TTACACCTGCTGGCAGGCAA VF2468 37 rev GCTGGTGTGAGCAAGAGGCA VF2468 38 fwd TGGCCAAGCCTGCCTAACTC VF2468 38 rev TGATCAGTTAGCCCTGGGGG VF2468 39 fwd CCCCTTCTGCTCCTGCTTCA VF2468 39 rev CCTTCCTTGCAGCTCAAACCC VF2468 40 fwd TGATTTTCAGCGTGGAGGGC VF2468 40 rev ACGGCAAAGCCAGAGCAAAG VF2468 41 fwd AAGCTGGCAGCCACTGTTCA VF2468 41 rev TCTCAGGGCTTCTGTGTGCG VF2468 42 fwd TCGATTCTCCATACACCATCAAT VF2468 42 rev GCAACCAACTCCCAACAGGG VF2468 43 fwd AGGTCCTGGCATTGTCTGGG VF2468 43 rev TGGTTGCCTGTTTCACACCC VF2468 45 fwd CTGGGAGGCAGCCAGTCAAG VF2468 45 rev GCCCTGTAAGCTGAAGCTGGA VF2468 46 fwd CAGGTGTGCATTTTGTTGCCA VF2468 46 rev GCCTGCCAGGTATTTCCTGTGT VF2468 47 fwd TGGGCGTGGTCATGTGAAAA VF2468 47 few AACTGCAAGTGGGCTCCCAG VF2468 48 fwd TTGATAAGGGCGGTGCCACT VF2468 48 rev TAGAGGGAGGTGCTTGCCCA VF2468 49 fwd CATCCCCTTGACCAACAGGC VF2468 49 rev GCTTGGGCACTGATCCTGCT VF2468 50 fwd ACTGCCAATGGACCCTCTCG VF2468 50 rev GAGTTGCCCAGGTCAGCCAT VF2468 51 fwd GGGGAGCTAGAATGGTGGGC VF2468 51 rev CAAGGTACACAGGTGACCAGG VF2468 52 fwd CCCATGCTGGTCCTGCTGTT VF2468 52 rev GGAGGCTCAGCGGAGAGGAT VF2468 53 fwd GGGGTCACCAGGGAAGGTTT VF2468 53 rev AGTTGCGGGGAGGTGCTACA VF2468 54 fwd TGCCCAGAGACCTTCCAAGC VF2468 54 rev TGGCCAAGGCCTCTCTAAGC VF2468 56 fwd GCCAATGTGCAATCGAGACG VF2468 55 rev TGCATGCCTCTGACTGATGCT VF2468 57 fwd TGACTTGAACTGGGTCCCCC VF2468 57 rev CTGGGGCTACAGCCCTCCTT VF2468 58 fwd CCCAATCCAGACACCACACG VF2468 58 rev TGCAGATTTTAGGGGTTGCCA VF2468 59 fwd GGTGAGGAAGGATGGGGGTT VF2468 59 rev GTAGGCTCTGCCACGCCAGT VF2468 60 fwd TGCCCATGTTGTTGCTCCAC VF2468 60 rev GACAAGTTAGACCATCCTAGCCCTCA VF2468 61 fwd TCACAGCTCCCCTTTCTCGG VF2468 61 rev TGTGCCTCCACTGACGCATT VF2468 62 fwd CCTAGGCACAGTGGGGGATG VF2468 62 rev GGGCTGACACACTGAGGGCT VF2468 63 fwd CCATGAGCACAATTGCCAAAA VF2468 63 rev TGAGTTATTTCGAAAGAGGAAACAGTG VF2468 64 fwd CTGCCAAGAACAGGAGGGGA VF2468 64 rev AGCCCATCTACCATCCAGCG VF2468 66 fwd ATCGGGGCAGGGCTAGAGTG VF2468 66 rev CCCCTGGCATTCCCTACACA VF2468 67 fwd GCCGTTAGTGCATTTGCCTG VF2468 67 rev TCCCTTTCAACCCCTGTAGTGC VF2468 68 fwd GTTCCTCCCAGAGTGGGGCT VF2468 68 rev ACTGAGGGAGGCAGCACTGG VF2468 69 fwd AGGCCTGGCGGTAACCTTG VF2468 69 rev AAGCTCCAGCCCTGTACCCC VF2468 70 fwd GGGATCCTACAGGATGGGACAA VF2468 70 rev CAGCCCAGGACAAGGGTAGC VF2468 71 fwd GCGACCAAATGTCCACTGGTT VF2468 71 rev TTCCGCAAGCAGTCCAGCTC VF2468 72 fwd GCACCAGCCTCTTCGATGGT VF2468 72 rev CGTTTGGCAGACTGTGGCGT VF2468 73 fwd AATGGGGCAAAAGGCAAGAAA VF2468 73 rev CAGACCTCGTGGTGCATGTG VF2468 74 fwd TGGCGAGATAGGCTCTGCTACA VF2468 74 rev TGGACAGGGAATTACTGAGACCAG VF2468 75 fwd TGTGGGCATGAGACCACAGG VF2468 75 rev TTTGACTCCCCCGCATTGTT VF2468 76 fwd TCCTATTTTCAGATGCACTCGAACC VF2468 76 rev GTGCTCACTGAAGCCCACCA VF2468 77 fwd GGACCTTCTTGCCCTCATGATTC VF2468 77 rev GGGAACTGTGCCTTTGCGTC VF2468 78 fwd CCTTGCAAAGGCTTGCCTAAA VF2468 78 rev GGCAGGCACCTGTAGTCCCA VF2468 79 fwd TGGCTTGCAGAGGAGGTGAG VF2468 79 rev GAGGGAAGGGTGTTGGCTTG VF2468 80 fwd GCTTCAGCACATCAGTGGCG VF2468 80 rev TTCGCCCAGCTCATCAACAA VF2468 81 fwd GGTGAGGCCACTGTAAGCCAA VF2468 81 rev TGGGCTGCCATGACAAACAG VF2468 83 fwd GAGTTGAGCTGTCAGCGGGG VF2468 83 rev GAAGCCAACTGCCTTGTGAGC VF2468 84 fwd TGTTTTCTGCAGTTTTGCAGGG VF2468 84 rev GGCTCAGGGAGTTTGAGCCA VF2468 85 fwd GCTCTGGCACCAGGCACACT VF2468 85 rev GGGAGAGAACCATGAATTTCCCA VF2468 86 fwd GCCAAACCGTTTCCAGGGAG VF2468 86 rev CCCACCCTATGCACAGAGCC VF2468 87 fwd CCTCAGCCAGTTGGAATCGG VF2468 87 rev CAACGGTTTAGTTTAGTTCCGGTTT VF2468 88 fwd TGGGTGGTGAAAATGGGGTT VF2468 88 rev GGTGGGGTATGCACTGGTCA VF2468 89 fwd GGAATGTGTGGAACAATTTCTTT VF2468 89 rev TTGCTTGCAGGGTGTGGAAA VF2468 90 fwd CCACAAGGGTCATCTGGGGA VF2468 90 rev GGGAGGCATCATCCACTGAG VF2468 91 fwd CCTGGAGTGGTTTGGCTTCG VF2468 91 rev TGGAGCCCTGGAGTTCTTGG VF2468 92 fwd GGCTCCTGGGGTCATTTTCC VF2468 92 rev TGTGCTCCATCCTCCTCCCT VF2468 93 fwd GTGTGTTTCCGCACACCCTG VF2468 93 rev GCTCTTGGCTTCCCAACCCT VF2468 94 fwd CCATCGCCGTGTCTGAGTGT VF2468 94 rev CAGCAGGAACATCATCCCCC VF2468 95 fwd AGGCAATGGCACCAAAATGG VF2468 95 rev GCAGCCTTCACCATACCTGTGA VF2468 96 fwd TTTTGACTTTGAGAACCCCCTGA VF2468 96 rev CCTTGTCCTTTCTCAGTTAGACACA VF2468 97 fwd GCTGAGTGCCAAAGCTCAGGGA VF2468 97 rev GGCAACACAGCAAGACCCCT

VF2468 Data

Potential VF2468 genomic off-target sites. The human genome was searched for DNA sequences surviving in vitro selection for VF2468 cleavage. Sites marked with an ‘X’ were found in the in vitro selection dataset. ‘T’ refers to the total number of mutations in the site, and ‘(+)’ and ‘(−)’ to the number of mutations in the (+) and (−) half-sites, respectively. The sequences of the sites are listed as they appear in the genome, therefore the (−) half-site is listed in the reverse sense as it is in the sequence profiles. Sequence (+) half-sites are SEQ ID NOs:925-3538 descending; sequence (−) half-sites are SEQ ID NOs:3539-6152 descending; full sequences with spacers are SEQ ID NOs: 6153-8766 descending.

VF2468 # of concentration mutations 4 2 1 0.5 T (−) (+) (−) site spacer (+) site nM nM nM nM 2 1 1 AGCAGCTTC CTTTT GAGTGAGAA X X X X 2 1 1 AGCATCGTC ATCAGA CAGTGAGGA X X X X 2 1 1 AGCAACGTC GTAGT GATTGAGGA X X X X 2 2 0 AGCTGGGTC ATGAG GAGTGAGGA X X X X 2 2 0 AGCTGGGTC ATGAG GAGTGAGGA X X X X 2 2 0 AGCAACTTC TGGAAA GAGTGAGGA X X X X 2 2 0 AGCTGAGTC TTAAG GAGTGAGGA X X X X 2 2 0 TCCAGCGTC CTCCCA GAGTGAGGA X X X X 2 2 0 TGCAGCGTT AAAATA GAGTGAGGA X X X X 2 2 0 AGCACCTTC AATTG GAGTGAGGA X X X X 2 2 0 TGCAGCGGC GTAGGG GAGTGAGGA X X X X 2 2 0 AGCAGGGTT CTTCAA GAGTGAGGA X X X X 2 2 0 AGCAGCATA GATATG GAGTGAGGA X X X X 2 2 0 AACAGCTTC TCTGAG GAGTGAGGA X X X X 2 2 0 TGCAGGGTC GGGCAG GAGTGAGGA X X X X 2 2 0 AGCAAAGTC AAACA GAGTGAGGA X X X X 2 2 0 AACAGCTTC TCGGGA GAGTGAGGA X X X X 2 2 0 AGTAGCGGC AAATT GAGTGAGGA X X X X 2 2 0 AGCTGAGTC CTAAA GAGTGAGGA X X X X 2 2 0 AGCAGCGAG AAAGA GAGTGAGGA X X X X 2 2 0 TGCAGTGTC CACAA GAGTGAGGA X X X X 2 2 0 AGCAGCATA ATAGCA GAGTGAGGA X X X X 2 2 0 AGCAGCATA TCAGG GAGTGAGGA X X X X 2 2 0 AGCAGCGGT CTTAG GAGTGAGGA X X X X 2 2 0 AACAGCTTC ATCTCG GAGTGAGGA X X X X 2 2 0 GGCAGAGTC CTAGA GAGTGAGGA X X X X 2 2 0 AGCTGTGTC TTGGA GAGTGAGGA X X X X 2 2 0 AGTGGCGTC CCAGT GAGTGAGGA X X X X 2 2 0 AGCTGTGTC CACAG GAGTGAGGA X X X X 3 1 2 AGCAGCGGC TTAAGG GGGTGAGGT X X X X 3 1 2 AGCAACGTC TAACCC GAGTGTTGA X X X X 3 1 2 AGCACCGTC CCCCT CAGTGAGGC X X X X 3 1 2 AGCAGCGGC GGCTG CAGTGAGGC X X X X 3 1 2 AGCAGTGTC TAAAAG GAGTGAGAT X X X X 3 1 2 AGCAACGTC CATAGT GTGTGAGAA X X X X 3 2 1 AGAAACGTC GTGGAG GAGTGAGGG X X X X 3 2 1 AGCATAGTC TAGGCC GAGTGAGGC X X X X 3 2 1 AGCAACTTC ATCTT GAGTGAGGG X X X X 3 2 1 AGCAGGGTG GCGTG GAGTGAGGC X X X X 3 2 1 AGCACGGTC ATGAT GAGTGAGGC X X X X 3 2 1 AGCATTGTC TCCTG GAGTGAGGG X X X X 3 2 1 AGCACCGTG GCTTC GAGTGAGGC X X X X 3 2 1 AGCAACTTC CTGGC GAGTGAGGG X X X X 3 2 1 AGCAACATC TGGTTG GAGTGAGGG X X X X 3 2 1 GGCAGCGGC CGCTGT GAGTGAGGT X X X X 3 2 1 AGCATTGTC TCATGT GAGTGAGGT X X X X 3 2 1 AGCAGCAGC TAGGG GAGTGAGGG X X X X 3 2 1 AGCAGCAGC CCACAG GAGTGAGGG X X X X 3 2 1 ATCAGAGTC TCTGG GAGTGAGGC X X X X 3 2 1 ATCAGTGTC CCTCAG GAGTGAGGC X X X X 3 2 1 AGCAACATC ATCTT GAGTGAGGG X X X X 3 2 1 AGCATGGTC CCAAG GAGTGAGGG X X X X 3 2 1 AGCAAAGTC TGTACT GAGTGAGGG X X X X 3 2 1 AGCAGCTCC TCTCC GAGTGAGGT X X X X 3 2 1 AGCAATGTC AAAAA GAGTGAGGC X X X X 3 2 1 AGTAGCGTT TTTAG GAGTGAGGT X X X X 3 2 1 GGCAGAGTC AGGGCT GAGTGAGGC X X X X 3 2 1 TGCAGCTTC ATGGT GAGTGAGGC X X X X 3 3 0 AGCATAGTT ACCTGG GAGTGAGGA X X X X 3 3 0 AGTAAAGTC TAAGTA GAGTGAGGA X X X X 3 3 0 AGCATTGTT CTGCG GAGTGAGGA X X X X 4 3 1 TGCAGTCTC CTTGG GAGTGAGGT X X X X 2 0 2 AGCAGCGTC CACTTC CAGAGAGGA X X X 2 1 1 AGCAGCGTG GACCCA GAGTGAGCA X X X 2 1 1 AGCAGCGCC AATCC GAGTGAGAA X X X 2 1 1 AGCAGCGGC AGGCT GAGAGAGGA X X X 2 1 1 AGCAGCTTC TGCCTT GAGTGAGTA X X X 2 1 1 AGCAGCTTC ACTGT CAGTGAGGA X X X 2 1 1 ATCAGCGTC TTCAG AAGTGAGGA X X X 2 1 1 AGCAGCGTG GACCCA GAGTGAGCA X X X 2 1 1 AGCAGGGTC AAGAAA GAGTGAGTA X X X 2 1 1 AGCAGCGTT ACACA GAGTGGGGA X X X 2 1 1 AGCAGCGGC AAGAGA GAATGAGGA X X X 2 1 1 AGCAGAGTC CAGGC AAGTGAGGA X X X 2 1 1 AGCAGAGTC CAGGC AAGTGAGGA X X X 2 1 1 AGCAGGGTC TGGGTA GAGTGATGA X X X 2 1 1 AGCAGCGTG GACCCA GAGTGAGCA X X X 2 2 0 AGCAGCAGC TAGCTA GAGTGAGGA X X X 2 2 0 AGGAGCTTC ACTAA GAGTGAGGA X X X 2 2 0 AGCAGCCTG CAATA GAGTGAGGA X X X 2 2 0 ACCAGTGTC TGAGCT GAGTGAGGA X X X 2 2 0 AACAGAGTC CCCAT GAGTGAGGA X X X 2 2 0 AGCAGCCTG GCCAGG GAGTGAGGA X X X 2 2 0 AGCAGCAGC AGTGA GAGTGAGGA X X X 2 2 0 ATCAGAGTC TTAGG GAGTGAGGA X X X 2 2 0 AGCGGGGTC TAGGGG GAGTGAGGA X X X 2 2 0 AGCAGCGGA CAAGT GAGTGAGGA X X X 3 0 3 AGCAGCGTC CCTGCC TAGGGAGGG X X X 3 0 3 AGCAGCGTC TTTTCT ATGTGAGGC X X X 3 0 3 AGCAGCGTC ACCTCT GTGTGGGGC X X X 3 0 3 AGCAGCGTC TAAGG GAGGGGGGT X X X 3 0 3 AGCAGCGTC TTGGG GTGTGGGGC X X X 3 0 3 AGCAGCGTC TAGAG TAGAGAGGT X X X 3 1 2 AGCAGGGTC TCCCAG GAGTGTGAA X X X 3 1 2 AGCAGTGTC TATTT CAGTGAGGG X X X 3 1 2 AGCAGGGTC AGCCCA GAGTGGGGG X X X 3 1 2 AGCAGGGTC AGGCA CAGTGAGGC X X X 3 1 2 AGCAGGGTC CTCTG GAGTGGGGG X X X 3 1 2 GGCAGCGTC CGGAG GAGTGAAGG X X X 3 1 2 GGCAGCGTC ACTCCA GAGTTAGGT X X X 3 1 2 AGCAGGGTC ATTCAT CAGTGAGGC X X X 3 1 2 AGCAGAGTC CTGTCA GAGGGAGGC X X X 3 1 2 AGCAGCATC TTCTG GAGTGAGAC X X X 3 1 2 AGCATCGTC TTTCT GTGTGAGGC X X X 3 1 2 AGCAGTGTC TCACAG GAGGGAGGG X X X 3 1 2 GGCAGCGTC CAGGA GAGAGAGGT X X X 3 1 2 AGCAGCGGC CCCGG GAGTTAGGT X X X 3 1 2 AGCAGCGGC GGGTGG GAGTGGGGG X X X 3 1 2 AGCAGTGTC CAGAC GAGGGAGGT X X X 3 1 2 AGCAGTGTC TATGA GAGGGAGGG X X X 3 1 2 AGCAGTGTC AGCCAT GAGGGAGGG X X X 3 1 2 AGCAGTGTC CCTGTG GAGGGAGGT X X X 3 1 2 AGCACCGTC TGCCA GAGTGGGCA X X X 3 2 1 AGCCACGTC CACAC TAGTGAGGA X X X 3 2 1 AGTAGCGCC AAAAG GAGTGAGGT X X X 3 2 1 AACAGGGTC TTTGAC GAGTGAGGC X X X 3 2 1 GGCAGGGTC TCAAT GAGTGAGGG X X X 3 2 1 AACAGGGTC CCTGA GAGTGAGGG X X X 3 2 1 AGGAGAGTC CAGGT GAGTGAGGG X X X 3 2 1 AGCAGCCGC CAACA GAGTGAGGG X X X 3 2 1 GGCAGAGTC AGTGTT GAGTGAGGG X X X 3 2 1 AGCAGTGTG TGAGCT GAGTGAGGC X X X 3 2 1 AGCATCTTC CAGTG GAGTGAGGG X X X 3 2 1 AGCAGAGTG GTTGA GAGTGAGGT X X X 3 2 1 ATCAGTGTC CCAGA GAGTGAGGG X X X 3 2 1 TTCAGCGTC CAAGAA GAGTGAGGT X X X 3 2 1 AGCAACTTC CGGACA GAGTAAGGA X X X 3 2 1 AGCAGCGGG AGATG GAGTGAGGC X X X 3 2 1 AGTAGCGTG GAGAG GAGTGAGGT X X X 3 2 1 AGCTGCATC TTTGG GAGTGAGGT X X X 3 2 1 ATCAGAGTC AAAGAA GAGTGAGGT X X X 3 2 1 AGCAGGATC TGAAAT GAGTGAGGT X X X 3 2 1 AGCCACGTC CAGTTT TAGTGAGGA X X X 3 2 1 AGCAATGTC TCAAAT CAGTGAGGA X X X 3 2 1 AGCAATGTC TGAAA CAGTGAGGA X X X 3 2 1 GGCTGCGTC ATCGG GAGTGAGGT X X X 3 2 1 GGCAGAGTC AAAAT GAGTGAGGT X X X 3 2 1 AGCAGTGTG CATGT GAGTGAGGT X X X 3 3 0 GGCAACATC AAACAG GAGTGAGGA X X X 3 3 0 CCCAGCGGC TGGCAG GAGTGAGGA X X X 3 3 0 AGCCTGGTC GGAGAG GAGTGAGGA X X X 3 3 0 TGCAGTCTC TATGG GAGTGAGGA X X X 3 3 0 AGCATTGTA GAGGC GAGTGAGGA X X X 3 3 0 AGCCTGGTC TCACA GAGTGAGGA X X X 3 3 0 AGCATAGTG AATAT GAGTGAGGA X X X 3 3 0 AGCAAAGGC ACCAG GAGTGAGGA X X X 3 3 0 AACATGGTC CACGT GAGTGAGGA X X X 3 3 0 AGCTTTGTC AACCTA GAGTGAGGA X X X 3 3 0 AGCAAAGGC AAAAA GAGTGAGGA X X X 3 3 0 ATCAAGGTC TTTTG GAGTGAGGA X X X 3 3 0 GCCAGTGTC TCGTCT GAGTGAGGA X X X 3 3 0 TGCAAAGTC AGATCT GAGTGAGGA X X X 4 1 3 AGCAACGTC TACAG GAGGAAGGT X X X 4 1 3 AGCAACGTC CCAGGA AAGTGAAGG X X X 4 2 2 GGCAGTGTC CAGTAG GAGTGAGAT X X X 4 2 2 AGCAAAGTC TCACA AAGTGAGGT X X X 4 3 1 TGCTGTGTC AAACCC GAGTGAGGT X X X 4 3 1 GGCAAGGTC TCTGTG GAGTGAGGG X X X 4 3 1 ATCAACGTG TCTCA GAGTGAGGC X X X 2 0 2 AGCAGCGTC TGAGGC GGGTGAGAA X X X 2 0 2 AGCAGCGTC TGCATG GTGTGGGGA X X X 2 1 1 AGCAGAGTC AGGCA GAGTGAGAA X X X 2 1 1 AGCAGCTTC ATTTAT GAGTGAGCA X X X 2 1 1 GGCAGCGTC CTTCT GAGTGAGCA X X X 2 1 1 AGCAGTGTC GTGAA GAGTCAGGA X X X 2 1 1 AGCAGCTTC CGGGGA GAGAGAGGA X X X 2 2 0 AGCAGCTGC GGACC GAGTGAGGA X X X 2 2 0 AGCAGTGGC ATTAA GAGTGAGGA X X X 2 2 0 AGCAGCATG CACAT GAGTGAGGA X X X 2 2 0 AGCAGCATG ACCAA GAGTGAGGA X X X 2 2 0 ACCAGGGTC TGTGGG GAGTGAGGA X X X 2 2 0 AGCAGCATG AAAAGG GAGTGAGGA X X X 2 2 0 AGCAGGGTG ATGGA GAGTGAGGA X X X 2 2 0 AGCAGTGAC CGAAG GAGTGAGGA X X X 2 2 0 AGCAGATTC CTCAG GAGTGAGGA X X X 2 2 0 ATCAGCGTG GCCAT GAGTGAGGA X X X 2 2 0 AGCAGGGGC AAGAGA GAGTGAGGA X X X 2 2 0 AGCGCCGTC CACAGG GAGTGAGGA X X X 3 0 3 AGCAGCGTC CCCTG GAGTGGCCA X X X 3 0 3 AGCAGCGTC CAGTGG GAGTGGGCC X X X 3 0 3 AGCAGCGTC CTTCCT CAGTGAGAC X X X 3 1 2 AGCAGCGGC GGCGGG GAGGGAGGC X X X 3 1 2 AGCAGAGTC TGTTGA GAGTGAGAC X X X 3 1 2 TGCAGCGTC AGAAG GTGTGAGGC X X X 3 1 2 AGCAGCGTG CCTCT GGGTGAGGC X X X 3 1 2 AGCAGCTTC CATCTG GAGTGAGTC X X X 3 1 2 AGCAGCATC TGCTCT TAGTGAGGC X X X 3 1 2 AGCAACGTC CTGCA GAGGGAGAA X X X 3 1 2 AGCAGCGGC CCGCA GAGGGAGGC X X X 3 1 2 AGCAACGTC AGCAA CAGTGAGAA X X X 3 1 2 AGTAGCGTC TCGAA GAGAGAGGC X X X 3 1 2 AGCAGCGTT TTCAG GAGGGAGGG X X X 3 1 2 AGCAGCGGC ACCCT GGGTGAGGC X X X 3 2 1 AGCAAGGTC AACTCA GAGTGAGAA X X X 3 2 1 AGCATGGTC AGTTTC TAGTGAGGA X X X 3 2 1 AGTAGGGTC ACGCCA GAGTGAGGC X X X 3 2 1 ATCAGGGTC CTGTT GAGTGAGGG X X X 3 2 1 AGCATGGTC TTTTTC TAGTGAGGA X X X 3 2 1 AGCAGGGTA AGAGGG GAGTGAGGG X X X 3 2 1 GGCAACGTC AACTCA GAGTGAGAA X X X 3 2 1 GCCAGCGTC TTGGGT GAGTGAGGT X X X 3 2 1 AGCAGCTTT CTGCT GAGTGAGGC X X X 3 2 1 AGCAGTGGC TGCGG GAGTGAGGC X X X 3 2 1 GGCAGCATC TGGGC GAGTGAGGC X X X 3 2 1 GGCAGCATC TGAAT GAGTGAGGC X X X 3 2 1 AGCAGTGTA TGTGG GAGTGAGGT X X X 3 2 1 AGGAGAGTC CCTGG GAGTGAGGC X X X 3 2 1 AGCATGGTC AGATTC TAGTGAGGA X X X 3 2 1 ATCAGGGTC TTGAGG GAGTGAGGT X X X 3 2 1 AACAGCGTG CTGTA GAGTGAGGT X X X 3 2 1 AGTAGCTTC TGTGG GAGTGAGGC X X X 3 2 1 AGCAACTTC TTGAT GAGTGAGAA X X X 3 2 1 AGCATGGTC AGGTTC TAGTGAGGA X X X 3 2 1 AGAAGTGTC AGAGTA GAGTGAGGC X X X 3 2 1 AACAGCGGC ATGGG GAGTGAGGC X X X 3 2 1 AGCAGTGGC ATCTAG GAGTGAGGC X X X 3 3 0 AAAAGTGTC ATATAG GAGTGAGGA X X X 3 3 0 AGCAATGGC TGGAT GAGTGAGGA X X X 3 3 0 GCCACCGTC GGTGAG GAGTGAGGA X X X 3 3 0 AAAAGTGTC AGTAGA GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGG GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGA GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGG GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGA GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGG GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGA GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGG GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGA GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGG GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGA GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGG GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGA GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGG GAGTGAGGA X X X 3 3 0 AACATTGTC TAGTGA GAGTGAGGA X X X 3 3 0 ATCAACTTC TTCAGG GAGTGAGGA X X X 3 3 0 AGCATGGTG ATTAA GAGTGAGGA X X X 4 3 1 AGTAGTCTC TGGCT GAGTGAGGT X X X 4 3 1 AGCATTGTT TCTCA GAGTGAGGT X X X 4 3 1 AGCAAGGTT AGGCT GAGTGAGGG X X X 4 3 1 AGCAGTCTT CCACCA GAGTGAGGC X X X 4 3 1 AGCATTGTT TGAGT GAGTGAGGT X X X 2 0 2 AGCAGCGTC CGCAGC AAGTTAGGA X X 2 0 2 AGCAGCGTC ACTACA GAGGCAGGA X X 2 1 1 GGCAGCGTC TCTCTG GGGTGAGGA X X 2 1 1 AGCAGAGTC TTGAA GAGTGAGTA X X 2 1 1 AGCAGCATC TATGC CAGTGAGGA X X 2 1 1 AGCAGAGTC TGGCA GAGAGAGGA X X 2 1 1 AGCAGTGTC CCTCA GAGTGTGGA X X 2 1 1 AGCAGCATC TTGGA GTGTGAGGA X X 2 1 1 AGCTGCGTC TTCTG GAGGGAGGA X X 2 1 1 AGCAGCTTC AGAAGA GAATGAGGA X X 2 1 1 AGCAGGGTC GAGGG GAGGGAGGA X X 2 1 1 AGCAGGGTC TGGTG CAGTGAGGA X X 2 1 1 AGCAGCATC CATGT CAGTGAGGA X X 2 1 1 AGCAGAGTC CCAAG GGGTGAGGA X X 2 1 1 AGCAGCCTC TGAAC AAGTGAGGA X X 2 1 1 AGCAGCCTC TAGGT AAGTGAGGA X X 2 1 1 AGCAGCTTC AGATTT GAGTTAGGA X X 2 1 1 AGCAGCCTC ACAGG CAGTGAGGA X X 2 1 1 AGCAGCATC AACAC CAGTGAGGA X X 2 1 1 AGCAGCGTG TCAGCT GTGTGAGGA X X 2 1 1 AGCAGCATC TATGC CAGTGAGGA X X 2 1 1 AGCAGCATC AATAAT AAGTGAGGA X X 2 1 1 AGCAGAGTC ACCCA GTGTGAGGA X X 2 1 1 GGCAGCGTC TGGGAG GAGTTAGGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCTGCGTC GTGAG AAGTGAGGA X X 2 1 1 AGCAGGGTC ACACA GGGTGAGGA X X 2 1 1 AGCAGAGTC AGAGAG GAGAGAGGA X X 2 1 1 AGCAGAGTC ACTGAC CAGTGAGGA X X 2 1 1 AGCAGTGTC TCCCA GAGTGTGGA X X 2 1 1 AGCAGTGTC TGAGTA GAGTGTGGA X X 2 1 1 AGCAGCATC CCGGG GAGTGAAGA X X 2 1 1 AACAGCGTC AAGGCA GAGTGAAGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCAGCGCC ATCTT GAGCGAGGA X X 2 1 1 AGCAGCATC CATGT CAGTGAGGA X X 2 1 1 AGCAGAGTC AGGGAG GAGTGAAGA X X 2 1 1 AGCAGCCTC ATGGTC AAGTGAGGA X X 2 1 1 AGCAGCATC GTGAGT GAGTGTGGA X X 2 1 1 AGCAGTGTC TAGCAC GAATGAGGA X X 2 1 1 AGCAGAGTC ACAGAA GAGAGAGGA X X 2 1 1 AGCAGCGTG GTTAA GAGTCAGGA X X 2 1 1 ACCAGCGTC TGGTGA GAGTGGGGA X X 2 1 1 AGCAGTGTC TTGCT GAGAGAGGA X X 2 1 1 AGCAGCGAC CTGGGC GAGTGAGAA X X 2 1 1 AGCAGTGTC TGCCGT GAGTGGGGA X X 2 1 1 AGCAGCGTA ATACA CAGTGAGGA X X 2 1 1 AGCAGCCTC TAGAGA AAGTGAGGA X X 2 1 1 AGCAGAGTC ACGGGT GTGTGAGGA X X 2 1 1 TGCAGCGTC ATCAA GAGTGTGGA X X 2 2 0 AGCAGGGAC CAGGTG GAGTGAGGA X X 2 2 0 AGCAGGCTC TAAAAT GAGTGAGGA X X 2 2 0 AGCAGCCTA GGAAT GAGTGAGGA X X 2 2 0 AGCATCCTC CAGGAG GAGTGAGGA X X 2 2 0 AGCAGAGTA CTCAGT GAGTGAGGA X X 2 2 0 AGCAGGGTA GAAGA GAGTGAGGA X X 2 2 0 AGCAGAGAC CTGAGG GAGTGAGGA X X 2 2 0 AGCAGAGTG GGCAA GAGTGAGGA X X 2 2 0 AGCTGCCTC GGTGGG GAGTGAGGA X X 2 2 0 AGGAGGGTC CTGGAT GAGTGAGGA X X 2 2 0 AGCAGACTC CTTGAT GAGTGAGGA X X 2 2 0 AGCAGAGTA TTTGG GAGTGAGGA X X 2 2 0 AGCAGAGTT GCCAG GAGTGAGGA X X 2 2 0 AGCAGCACC AAAATG GAGTGAGGA X X 2 2 0 AGCAGGATC AGGTTA GAGTGAGGA X X 2 2 0 TGCAGCATC CTTCAG GAGTGAGGA X X 2 2 0 AGCAGAGTG TGGTG GAGTGAGGA X X 2 2 0 AGCAGTGCC TACCA GAGTGAGGA X X 2 2 0 AGCAGAGTA CCCAT GAGTGAGGA X X 2 2 0 AGCAGAGTG AAAGGA GAGTGAGGA X X 2 2 0 AGCAGGATC AAGAAA GAGTGAGGA X X 2 2 0 AGCAGCTTG TGTCAT GAGTGAGGA X X 2 2 0 AGCAGAGTA GGTTGT GAGTGAGGA X X 3 0 3 AGCAGCGTC TGCAGT TTGTGGGGA X X 3 0 3 AGCAGCGTC AGGGGA TTGTGGGGA X X 3 0 3 AGCAGCGTC CAAGA GAGTTACAA X X 3 0 3 AGCAGCGTC AAAGT TTGAGAGGA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC TTTTT GAGAGAAGG X X 3 0 3 AGCAGCGTC GGGGA GAGTTGGGG X X 3 0 3 AGCAGCGTC TCCAG GAACGTGGA X X 3 0 3 AGCAGCGTC CTTGGG GAGTTTGGG X X 3 0 3 AGCAGCGTC GTCAC AGGGGAGGA X X 3 0 3 AGCAGCGTC CAAAA GGCTGAGGG X X 3 0 3 AGCAGCGTC CGTCG CAGTGGGGC X X 3 0 3 AGCAGCGTC CGCACT GAGGGGGCA X X 3 0 3 AGCAGCGTC TCTGC GGGAGAGGC X X 3 0 3 AGCAGCGTC ATCTT GAGTGGAGC X X 3 0 3 AGCAGCGTC AGCGA CAGAGAGGC X X 3 0 3 AGCAGCGTC TGTAT GTGTCAGAA X X 3 0 3 AGCAGCGTC ATTAGG GCATGAGCA X X 3 0 3 AGCAGCGTC GATGGA AAGGGAAGA X X 3 0 3 AGCAGCGTC AGGAA GAGTTGTGA X X 3 0 3 AGCAGCGTC TACCGT GAGTGCTCA X X 3 0 3 AGCAGCGTC AGGGT TTGAGAGGA X X 3 0 3 AGCAGCGTC ATGAGT GTGTAATGA X X 3 0 3 AGCAGCGTC TCTTTA GAGTGGGTT X X 3 0 3 AGCAGCGTC CTGTG GAGGCAGAA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC AGGCTT CAGTGTGAA X X 3 0 3 AGCAGCGTC AGGGT TTGAGAGGA X X 3 0 3 AGCAGCGTC ACACTC TACTGAGGT X X 3 0 3 AGCAGCGTC ACATGC CAGCGAGGT X X 3 0 3 AGCAGCGTC CATGGT GACAGAGGT X X 3 0 3 AGCAGCGTC TTCCCT GAGAGAGCT X X 3 0 3 AGCAGCGTC CAGGA GAGGAAGGC X X 3 0 3 AGCAGCGTC ATACA GGCTGAGGT X X 3 0 3 AGCAGCGTC TGCAT GAAGGAGGT X X 3 0 3 AGCAGCGTC CCAGT GAGCGATGG X X 3 0 3 AGCAGCGTC TTGCA AAGGGAGAA X X 3 0 3 AGCAGCGTC AGGGT TTGAGAGGA X X 3 0 3 AGCAGCGTC CACGT GTGTGCGGT X X 3 0 3 AGCAGCGTC AGCCTC TAGAGGGGA X X 3 0 3 AGCAGCGTC CGCAG GAGGTAGGG X X 3 0 3 AGCAGCGTC CAAGA GTGTTACGA X X 3 0 3 AGCAGCGTC CTAGC CTGTGAGGG X X 3 0 3 AGCAGCGTC CTCCTG GAGGGAGAG X X 3 0 3 AGCAGCGTC AGGGAG GAGGGGAGA X X 3 0 3 AGCAGCGTC CCCCCG CAGTGATGG X X 3 0 3 AGCAGCGTC TCCTGA GAGAGAAGG X X 3 0 3 AGCAGCGTC TGTCCT GAGTCCAGA X X 3 0 3 AGCAGCGTC AAGGAT TAGAGAGTA X X 3 0 3 AGCAGCGTC TCCTGA GAGAGAAGG X X 3 1 2 AGTAGCGTC CTAAT GAGTGTGAA X X 3 1 2 AGCAGCTTC TCCATG GAGTGAGAC X X 3 1 2 AGCAGGGTC GGGGA GAGGGAGGG X X 3 1 2 AGCAGCATC CAGACT CAGTGAGGT X X 3 1 2 AGCAGGGTC AGCTAA GAGGGAGGC X X 3 1 2 AGCAGCGGC AGCGA GAGTGATGT X X 3 1 2 GGCAGCGTC TGACG GAGTGAGTG X X 3 1 2 AGCAGTGTC AGGTAG GAGAGAGGC X X 3 1 2 AGCAGGGTC TGAGTG GAGTAAGGT X X 3 1 2 AGCAGTGTC AGCTGG TAGTGAGAA X X 3 1 2 AGCACCGTC TGGGG GAGGGAAGA X X 3 1 2 AGCAGCATC AGCATG GAGGGAGGC X X 3 1 2 AGCAGCCTC GGTCAA GAGTGAGAG X X 3 1 2 GGCAGCGTC AATAA AAGTGAGGG X X 3 1 2 AGCAACGTC GGCAG CAGTGGGGA X X 3 1 2 AGCAACGTC AGCAAA GTCTGAGGA X X 3 1 2 AGCAGGGTC AGTGTC TAGTGAGAA X X 3 1 2 AGCAGGGTC AGGATG GAGTGGGGT X X 3 1 2 AGCAGTGTC AGTGAA CAGTGAGGT X X 3 1 2 AGCAGGGTC AGTGCC TAGTGAGGG X X 3 1 2 AGCAGCGTA CGGACT GAGTGAGCC X X 3 1 2 AGCAGCTTC CCCAGT AAGTGAGAA X X 3 1 2 AGCAGCGGC ACCTC GAGAGAGAA X X 3 1 2 AGCAGTGTC CTCAC CAGTAAGGA X X 3 1 2 AGCAGGGTC TGTTA GAGTGAGTG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCACCGTC ATCTAA GGGTGAGGC X X 3 1 2 AGCATCGTC CTGTG GAGCGAGGG X X 3 1 2 AGCAGGGTC CTTACT CAGTGAGGT X X 3 1 2 AGCAGAGTC TGAGA GTGTGAGGT X X 3 1 2 AGCAGCGTG CAGTGA CAGTGAGGC X X 3 1 2 AGCACCGTC ATTGGA GAGGGAGAA X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGAGTC GCTGCA GAGTGAGCC X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGAGTC CTTGG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCGTA TGCATA CAGTGAGGG X X 3 1 2 AGCAGTGTC AGGCTG GTGTGAGAA X X 3 1 2 AGCAGAGTC GGCGTC TAGTGAGGG X X 3 1 2 AGCAGCGTG GGCCGG GAGGGAGGT X X 3 1 2 GGCAGCGTC CGATT CAGTGAGGG X X 3 1 2 AGCAGCTTC ACTGAA GAGGGAGGC X X 3 1 2 ATCAGCGTC TCTGG GAGTGGGGC X X 3 1 2 AGCAGCGGC AGGCGA GAGTGACAA X X 3 1 2 AGCAGCTTC AACGT GAGTGATGT X X 3 1 2 AGCAGCTTC CTGGG GAGTGAGTT X X 3 1 2 AGCAGCATC TCGTG GAGGGAGGC X X 3 1 2 AGCAGAGTC TTCAG GAGAGAGGC X X 3 1 2 AGCAGGGTC AAGTTC CAGTGAGGG X X 3 1 2 AGCAGAGTC AGTCTT GAGTGAGTT X X 3 1 2 AGCAGAGTC AGACTT GAGTGAGTT X X 3 1 2 TGCAGCGTC CAGAT GAGGGAGGT X X 3 1 2 AGCATCGTC AGAAT GGGTGAGGG X X 3 1 2 AGCAGTGTC CAGCTC CAGTGAGGC X X 3 1 2 AGCAGCTTC TAAAAG GAGAGAGGT X X 3 1 2 AGCAGGGTC CATGAG GAGTGAGCC X X 3 1 2 AGCAGTGTC ACCACA GAGTGAAGG X X 3 1 2 AGCAGGGTC AGGTTT TAGTGAGGG X X 3 1 2 AGCAGCATC AATGTC TAGTGAGGG X X 3 1 2 AGCAGTGTC CCGCAC GAGGAAGGA X X 3 1 2 AGCAGCTTC TTGTGA GAGAGAGGT X X 3 1 2 AGCAGAGTC CTAAGC GGGTGAGGG X X 3 1 2 AGCAGTGTC AAGTA GAGTGAAGG X X 3 1 2 AGCATCGTC AAGTTC TGGTGAGGA X X 3 1 2 AGCAGGGTC CCTGCT GAGAGAGGG X X 3 1 2 AGCAGAGTC AAGTCA GAGAGAGGC X X 3 1 2 AGCAGCGGC TGATG GACTGAGGC X X 3 1 2 AGCAGAGTC CAGTGG GTGTGAGGC X X 3 1 2 AGCAGCGGC TGATG GACTGAGGC X X 3 1 2 AGCAGCGGC AGCCGA GAGAGAGGG X X 3 1 2 AGCAGCGGC TGATG GACTGAGGC X X 3 1 2 AGCAGCGGC TGATG GACTGAGGC X X 3 1 2 AGCAGCGGC TGATG GACTGAGGC X X 3 1 2 AGCAGCGGC TGATG GACTGAGGC X X 3 1 2 AGCAGCGGC TGATG GACTGAGGC X X 3 1 2 AGCAGCGGC AGCCGA GAGAGAGGG X X 3 1 2 AGCAGCGGC TGATG GACTGAGGC X X 3 1 2 TGCAGCGTC TTGTT TAGTGAGGC X X 3 1 2 AGCAGTGTC AGGCTG GTGTGAGAA X X 3 1 2 AGCAGCGTA GAGTGG GAATGAGGG X X 3 1 2 AGCATCGTC ACAGGA GGGTGAGGT X X 3 1 2 AGCAGCGGC ACCCA GAATGAGGG X X 3 1 2 AGCAGCGTT ATTTCA GAGTGTGGT X X 3 1 2 AGCAGAGTC GCTCCA GAGTGAGCC X X 3 1 2 AGCAGTGTC ATCTTT GAGTGGGAA X X 3 1 2 AGCAGCATC TCCTAG CAGTGAGGG X X 3 1 2 AGCAACGTC AGTGG GACTGAGGG X X 3 1 2 AGCACCGTC ATCTT GAGTGAGCT X X 3 1 2 AGCAGGGTC CTGAG GGGAGAGGA X X 3 1 2 GGCAGCGTC AGGAGA GAGTGATGT X X 3 1 2 AGCATCGTC GGGGAG GAGTGGGAA X X 3 1 2 AGCAGTGTC TGTGCT CAGTGAGGT X X 3 1 2 AGCAGTGTC AGTCCT GAGAGAGCA X X 3 1 2 AGCAGCGTT GCTTTC TAGTGAGGT X X 3 1 2 AGCAGCGGC GACAGG GAGAGAGGG X X 3 1 2 AGCACCGTC CTGAAA CAGTGAGTA X X 3 1 2 AGCAGTGTC TGCTGG GAGGGTGGA X X 3 1 2 AGCAGCGCC CTGTGG GAGGGAGGT X X 3 1 2 AGCAGAGTC AGAAA GAGTAAGGC X X 3 1 2 AGCAGCTTC TCTAAG GAGTGGGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ATCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGCTTC CTGCTC CAGTGAGGG X X 3 1 2 AGCAGCTTC ACCTG GAGGGAGGG X X 3 1 2 AGCAGAGTC AAGAGG GTGTGAGGG X X 3 1 2 AGCAGGGTC CTGAAG GAGGGAGGG X X 3 1 2 AGCAGGGTC AGCCCA GAGGGAGGC X X 3 1 2 GGCAGCGTC ATTTT GAGTGGGGG X X 3 1 2 AGCAGCGTG TGGCA GAGAGAGGG X X 3 1 2 AGCACCGTC CCCGAG GTGGGAGGA X X 3 1 2 AGCAGCTTC CCATC GGGTGAGGG X X 3 1 2 AGCAGCATC TGTGGA CAGTGAGGT X X 3 1 2 AGCAGCGTG CTGGAT GAGTGTGGT X X 3 1 2 AGCAGCGGC AGGCAC CAGTGAGGG X X 3 1 2 AGCAGGGTC AGGGGT GAGTGGGGT X X 3 1 2 AGCAGCGGC GAACA GAGCGGGGA X X 3 1 2 AGCTGCGTC TCTGGG AAGTGAGGG X X 3 1 2 AGCAGGGTC ATGACA GAGAGAGGG X X 3 1 2 AGCAGCATC TGGCA GAGTAAGGG X X 3 1 2 AGCAGTGTC CACCT GAGTTAGGT X X 3 1 2 AGCAGCGAC GGCGG GTGTGAGGC X X 3 1 2 AGCAGGGTC ACACTA AAGTGAGGC X X 3 2 1 AGCTGTGTC ATGAC AAGTGAGGA X X 3 2 1 AGCTGGGTC ATGTG AAGTGAGGA X X 3 2 1 AGCTGGGTC ATGTG AAGTGAGGA X X 3 2 1 GGCAGCGGC CGGAAA AAGTGAGGA X X 3 2 1 AGCATGGTC AATGA CAGTGAGGA X X 3 2 1 ATCAGCCTC TTGTAG GAGTGAGGG X X 3 2 1 AGCATGGTC ATGAA CAGTGAGGA X X 3 2 1 AGCAGGGGC ATGAGA GAGTGAGGT X X 3 2 1 AACAGCGTG GCGGA GAGTGAGGG X X 3 2 1 AACAGAGTC CAGGAA GAGTGAGGT X X 3 2 1 AACAGCATC AGCTCT GAGTGAGGC X X 3 2 1 ATCAGTGTC AGTGAG CAGTGAGGA X X 3 2 1 AGCAGCTGC ATGAT GAGTGAGGT X X 3 2 1 AGCAGGGTT GATCA GAGGGAGGA X X 3 2 1 AGCATAGTC CAGAT TAGTGAGGA X X 3 2 1 AGCAGCAAC CTTAA GAGTGAGGG X X 3 2 1 AGCTACGTC TAAGG GAGAGAGGA X X 3 2 1 AGCAGCATT GGTCCT GAGTGAGGT X X 3 2 1 AGCATTGTC ATGAA GAGGGAGGA X X 3 2 1 AGCAGCACC TGGCCT GAGTGAGGG X X 3 2 1 AGCAGGGTT GGGCA GAGGGAGGA X X 3 2 1 AGTAGAGTC TGACTA AAGTGAGGA X X 3 2 1 AGCAACGTG AGTGT GAGCGAGGA X X 3 2 1 AGCAAGGTC CCACT CAGTGAGGA X X 3 2 1 AGCAGCCAC AAGGT GAGTGAGGG X X 3 2 1 AGCAATGTC AGGGA AAGTGAGGA X X 3 2 1 AGCAGCTAC TCCAGA GAGTGAGGT X X 3 2 1 AGCAGCTGC AGCAG GGGTGAGGA X X 3 2 1 AGCAGGGGC AGCAT GAGTGAGGT X X 3 2 1 AGCAACGTG ACCTAC TAGTGAGGA X X 3 2 1 AACAGCGTA AGTAC AAGTGAGGA X X 3 2 1 TGCACCGTC AGTAA CAGTGAGGA X X 3 2 1 AGCAGTGTG TCCCAA GAGTGAGGG X X 3 2 1 AGCAGCTGC AATTAT GAGAGAGGA X X 3 2 1 AGCACCTTC TAGCTA GAGTGAGCA X X 3 2 1 AGCAAGGTC AGAAG GAGTAAGGA X X 3 2 1 AGCTGCGTG GGAGCA GAGTGAGGC X X 3 2 1 AGCAAGGTC CTAGT GAGTGAAGA X X 3 2 1 AGCAGATTC AGAAG GAGTGAGGG X X 3 2 1 AGCAAAGTC ATTAGA GAGTAAGGA X X 3 2 1 TGCAGGGTC TTCCC GAGTGAGGG X X 3 2 1 AGCAGAATC TTCTGG GAGTGAGGT X X 3 2 1 AGCTGAGTC CCTAGA GAGGGAGGA X X 3 2 1 AGCATTGTC CAGAAA CAGTGAGGA X X 3 2 1 TGCAGGGTC CCAGC GAGTGAGGG X X 3 2 1 AGCAACTTC ATGTAT GAGTGTGGA X X 3 2 1 AGCAGCTGC CTGCTG GAGTGAGGG X X 3 2 1 AGCAGGGTT GGGGA GAGGGAGGA X X 3 2 1 AGCAAGGTC ACTGA GAGTAAGGA X X 3 2 1 AGCTGTGTC AAAGG AAGTGAGGA X X 3 2 1 AACAGCATC TTAGGG GAGTGAGGG X X 3 2 1 AGAAGCTTC TAGGCT GAGTGAGGC X X 3 2 1 AGCAGAGTT TGGGGT GAGTGAGAA X X 3 2 1 AGCAGAGTT TGCTTT GAGTGAGTA X X 3 2 1 AGGAGGGTC TGAAGA GAGTGAGGG X X 3 2 1 AGCAACTTC AGCAAA GTGTGAGGA X X 3 2 1 AGCAGCACC CTGGA GAGTGAGGG X X 3 2 1 AGCAAAGTC TGGGAG AAGTGAGGA X X 3 2 1 AGCAACGTG ACCCCT GAGTGGGGA X X 3 2 1 AGCAGGGTG TATAA GAGTGAGGG X X 3 2 1 AGCAGGTTC TTGGGA GAGTGAGGT X X 3 2 1 AGCAGCTTG TTTCT GAGTGAGGG X X 3 2 1 AGCAGTGTT GCATTA AAGTGAGGA X X 3 2 1 AGAGGCGTC TGAGCA GAGTGAGGG X X 3 2 1 AGCAGTGAC TTAGGA AAGTGAGGA X X 3 2 1 AGCACCTTC CGAGT GAGTGAGCA X X 3 2 1 ATCAGTGTC TCCTC CAGTGAGGA X X 3 2 1 AGCAGCAGC AGGAA GAGTGAGGC X X 3 2 1 AGCAGTGAC ACCTG AAGTGAGGA X X 3 2 1 AGCAGGGTT CACAGG GAGGGAGGA X X 3 2 1 AGCTGCGGC AGGCCC GAGTGAGGC X X 3 2 1 AGCAACATC TGCTA CAGTGAGGA X X 3 2 1 AGCAACGTA TAATC TAGTGAGGA X X 3 2 1 AGCAGGATC GCCTGT GAGTGAGGG X X 3 2 1 AGCAGCAAC ATGGGA GAGTGAGGT X X 3 2 1 AGTAGCGGC TTCACA GAGTGAGAA X X 3 2 1 AGCAGCAGC ATCCT GAGTGAGGG X X 3 2 1 AGCAGCTGC CAGAA GAGAGAGGA X X 3 2 1 AGCACCGTT GTTAG AAGTGAGGA X X 3 2 1 AGCAGGGTG GTTAA GAGTGAGGG X X 3 2 1 AGCTGGGTC TTGGGA AAGTGAGGA X X 3 2 1 ACCACCGTC GCGGA AAGTGAGGA X X 3 2 1 AGAAGCTTC AGTTG GAGTGAGGT X X 3 2 1 AGCAGAGGC ACCTTT GAGTGAGGT X X 3 2 1 AGCATCGTT GAGCT CAGTGAGGA X X 3 2 1 AGAAGCGTG TGCTG GAGTGAGGC X X 3 2 1 GACAGCGTC TGGGAG GTGTGAGGA X X 3 2 1 AGCAGAGAC CTGCAT GAGTGAGGG X X 3 2 1 AGCAAAGTC CTAAGG AAGTGAGGA X X 3 2 1 AGCATTGTC TCTAGA GAATGAGGA X X 3 2 1 AGCAAAGTC TTGAGA GAGCGAGGA X X 3 2 1 AGCACAGTC CCCGTT GAGAGAGGA X X 3 2 1 AGCAGCAGC ACTGA GAGTGAGGC X X 3 2 1 AGCAGGGTG GGGTGT GAGTGAGGT X X 3 2 1 AGGAGCATC GCGCAG GAGTGAGGC X X 3 2 1 AGCTGGGTC ATGTG AAGTGAGGA X X 3 2 1 AGCTGTGTC ATGAC AAGTGAGGA X X 3 2 1 AGCTGTGTC ATGAC AAGTGAGGA X X 3 2 1 AGGAGCGTA TCTTCT GAGTGAGGC X X 3 2 1 AGCAGCCAC AGCGA GAGTGAGGG X X 3 2 1 AGCAGCATG TGCAGG GAGTGAGGC X X 3 2 1 AGCATTGTC TTTTGA GAGTGAGAA X X 3 2 1 AGCAGCCTG GACGT GAGTGAGGT X X 3 2 1 AGCAGCTCC AGCGA GAGTGAGGG X X 3 2 1 AGCAGCAGC TAGGGA GAGTGAGGC X X 3 2 1 AGCAACTTC AATCAG GAGTGTGGA X X 3 2 1 AGCAGAGTA GCTTT GAGTGAGGG X X 3 2 1 AGCAGCCTT GTGTG GAGTGAGGT X X 3 2 1 AGCAGTGTT TCTGA AAGTGAGGA X X 3 2 1 AGAAGCATC TGTAT GAGTGAGGC X X 3 2 1 AGCAGGGTA AACAAA GAGTGAGGT X X 3 2 1 AGCAGAGTT AGGAGA GAGTGAGGG X X 3 2 1 AGCAGAGGC TGGGGA GAGTGAGGG X X 3 2 1 AGCAACATC TTATA GAGTGAGCA X X 3 2 1 AGCAGAGTA TGTCA GAGTGAGGT X X 3 2 1 AGCATCGTT GAGCT GAGTGAAGA X X 3 2 1 AGAAGCTTC CAGAAT GAGTGAGGC X X 3 2 1 ATCAGCGGC AGATGG CAGTGAGGA X X 3 2 1 AGCAGAATC TCTGG GAGTGAGGC X X 3 2 1 AGCTACGTC ACCTT GAGGGAGGA X X 3 2 1 AGCAATGTC AACAA GAGTGAGAA X X 3 2 1 AGCATTGTC ATGGTG GAGGGAGGA X X 3 2 1 AGCAGAGGC GGGAA AAGTGAGGA X X 3 2 1 AGCACGGTC GGGTAC TAGTGAGGA X X 3 2 1 AGCAACATC TATAT GAGTGAGCA X X 3 2 1 AGCAGGGTT GGAGT GAGGGAGGA X X 3 2 1 AGCAGCTGC AGCACC GAGTGAGGG X X 3 2 1 AGCAGTGTG TGGGAG GAGTGAGGG X X 3 2 1 AACAGAGTC TGGTT GAGTGAGGC X X 3 2 1 GGCAGTGTC TGGCA AAGTGAGGA X X 3 2 1 AGCAGTGTG TGGGAG GAGTGAGGG X X 3 2 1 AGCAAGGTC CAGACA AAGTGAGGA X X 3 2 1 AGCAGTGTG TGGGAG GAGTGAGGG X X 3 2 1 AGCAGTGTG TGGGAG GAGTGAGGG X X 3 2 1 AGCAGTGTG TGGGAG GAGTGAGGG X X 3 2 1 AGCAGTGTG TGGGAG GAGTGAGGG X X 3 2 1 AGCAGTGTG TGGGAG GAGTGAGGG X X 3 2 1 AGCAGCATG AGAGG GAGTGAGGG X X 3 2 1 AGCACTGTC ATTAT AAGTGAGGA X X 3 2 1 GGCAGTGTC TGGAAA AAGTGAGGA X X 3 2 1 CACAGCGTC ACCCTG GAGTGAGAA X X 3 2 1 AGCACCTTC CTGGCT GAGTGAGGG X X 3 2 1 AGCACAGTC CCAAAT GAGTGAGAA X X 3 2 1 AGCAGATTC TGGTA GAGTGAGGG X X 3 2 1 AGGAGGGTC AGCCT GAGTGAGGG X X 3 2 1 AGCAACGTG GCGGG AAGTGAGGA X X 3 2 1 AGCGGCGTT GAGCTT GAGTGAGGC X X 3 2 1 AGGAGTGTC TGGGT GAGTGAGGT X X 3 2 1 AGCTGCTTC ACTGAT GAGTGAGGC X X 3 2 1 AGCAACATC CACTG CAGTGAGGA X X 3 2 1 AGCATAGTC GGACAA TAGTGAGGA X X 3 2 1 AGCAACATC AAACCT GAGAGAGGA X X 3 2 1 GGCAGCGCC CATCT GAGTGAGGG X X 3 2 1 AGCAGAGTG TCCAA GAGTGAGGG X X 3 2 1 AGCAAAGTC CTAGAT GAGGGAGGA X X 3 2 1 GACAGCGTC ACACA CAGTGAGGA X X 3 2 1 AGCGGCGGC TGGAT GAGTGAGGG X X 3 2 1 AGCCGCATC ATCAA GAGTGAGGC X X 3 2 1 AGCAAAGTC CCCAG GAGGGAGGA X X 3 2 1 AGCAGGTTC TAAGA GAGTGAGGT X X 3 2 1 AGCTGGGTC ACACG AAGTGAGGA X X 3 2 1 AGCAGAGAC TGAATG GAGTGAGGG X X 3 2 1 AGCAGAGGC TTAAAG GAGTGAGGG X X 3 2 1 AGCTGAGTC TAGCCA AAGTGAGGA X X 3 2 1 AGTAGAGTC TTCCA GAGTGAGAA X X 3 2 1 TGCAGCGAC AACAG GAGTGAGGT X X 3 2 1 AGCAGCTGC CTCCG GAGAGAGGA X X 3 2 1 AGCAGCATG GCCCT GAGTGAGGG X X 3 2 1 AGCTGAGTC CCAAA GAGTGAGAA X X 3 2 1 AGCAACATC TGCTA CAGTGAGGA X X 3 2 1 AGCAACATC TGCTA CAGTGAGGA X X 3 2 1 ACCAGCTTC CTGCT GAGTGAGGT X X 3 2 1 AGCAGCATT ATTCT GAGTGAGGG X X 3 2 1 AGGAGTGTC GACAAG GAGTGAGGG X X 3 2 1 AGAAGCGGC TGCAG GAGTGAGGG X X 3 2 1 AGCAGCCAC AGACTA GAGTGAGGC X X 3 2 1 AGCAGCAGC AGCAG GAGTGAGGC X X 3 2 1 AGCACAGTC CGCAGG GAGGGAGGA X X 3 2 1 AGCTGCGGC GAATGA GAGTGAGGG X X 3 2 1 AGCAAGGTC TTATA GGGTGAGGA X X 3 2 1 AGCACCTTC TCCAT GAGTGGGGA X X 3 2 1 AGCAGCATG ATCCTG GAGTGAGGC X X 3 2 1 AGCAAGGTC AAGAGA GAGTGAGCA X X 3 2 1 AGCATGGTC AAAGCT GAGTGAGAA X X 3 2 1 AGCAGCATG ATCTTG GAGTGAGGC X X 3 2 1 AGCAGGGTG GGGTGT GAGTGAGGT X X 3 3 0 AGAGGTGTC GCCAT GAGTGAGGA X X 3 3 0 GTCAGGGTC ATCAG GAGTGAGGA X X 3 3 0 TGCACTGTC TCTCCC GAGTGAGGA X X 3 3 0 TGCGGAGTC GAGGGT GAGTGAGGA X X 3 3 0 AGAAACGTT CTTGCT GAGTGAGGA X X 3 3 0 AGGAGCAAC ATGCT GAGTGAGGA X X 3 3 0 CGCTGTGTC CCCGGG GAGTGAGGA X X 3 3 0 AGCGTGGTC ACTAGG GAGTGAGGA X X 3 3 0 AGCAGGTCC TTGAA GAGTGAGGA X X 3 3 0 GGCTGTGTC ATTCAG GAGTGAGGA X X 3 3 0 TGCAGAGTT AGAGGT GAGTGAGGA X X 3 3 0 ATCATGGTC AGAAAA GAGTGAGGA X X 3 3 0 AGCAACGCG GTGAGG GAGTGAGGA X X 3 3 0 TGAAGTGTC AGCTC GAGTGAGGA X X 3 3 0 AGCAACTCC GTCTT GAGTGAGGA X X 3 3 0 AGAAATGTC TTCCAG GAGTGAGGA X X 3 3 0 GGCAGGGTA TCACAG GAGTGAGGA X X 3 3 0 AGCAACATG GAGTT GAGTGAGGA X X 3 3 0 GACAGCGTG GCCAGT GAGTGAGGA X X 3 3 0 GGCTGAGTC ACTCT GAGTGAGGA X X 3 3 0 TGCAGAGTT TTGTG GAGTGAGGA X X 3 3 0 AGCTGAGTG CTGGAT GAGTGAGGA X X 3 3 0 AACTGAGTC TCTGA GAGTGAGGA X X 3 3 0 AACATAGTC TGTACA GAGTGAGGA X X 3 3 0 AGCTGGGTG ACAGT GAGTGAGGA X X 3 3 0 AGCACCATA TGGCT GAGTGAGGA X X 3 3 0 ATCAGGTTC CTTCT GAGTGAGGA X X 3 3 0 ACCACGGTC AGGTCT GAGTGAGGA X X 3 3 0 ACCACGGTC AGGTCT GAGTGAGGA X X 3 3 0 ACCACGGTC AGGTCT GAGTGAGGA X X 3 3 0 ACCACGGTC AGGTCT GAGTGAGGA X X 3 3 0 ACCATGGTC AAGTCT GAGTGAGGA X X 3 3 0 AGAAACTTC CTCTC GAGTGAGGA X X 3 3 0 CACAGCTTC TCACAG GAGTGAGGA X X 3 3 0 ATCATGGTC TTAGA GAGTGAGGA X X 3 3 0 AGCAGTGAT TGAGG GAGTGAGGA X X 3 3 0 ACCAAGGTC ACACT GAGTGAGGA X X 3 3 0 AGCCCCTTC CTAGAG GAGTGAGGA X X 3 3 0 CTCAGTGTC TAAGCA GAGTGAGGA X X 3 3 0 AGTTGCTTC CTGAG GAGTGAGGA X X 3 3 0 AAGAGAGTC TGAAA GAGTGAGGA X X 3 3 0 GGCAGTGTG GTCACC GAGTGAGGA X X 3 3 0 TGCAGAGTT GGGTCA GAGTGAGGA X X 3 3 0 AGCCTCGTT GCCAGA GAGTGAGGA X X 3 3 0 ATCATCTTC AAGTAA GAGTGAGGA X X 3 3 0 AGTAGTGTG TGAAGG GAGTGAGGA X X 3 3 0 AGCCTCGTG TCCTCA GAGTGAGGA X X 3 3 0 AAAAGCGTT TGGGAA GAGTGAGGA X X 3 3 0 ACTAGAGTC CCCCAA GAGTGAGGA X X 3 3 0 GGCGGCGGC GAAGG GAGTGAGGA X X 3 3 0 ATGAGAGTC CTGGG GAGTGAGGA X X 3 3 0 AGCACAGTG GCCTGA GAGTGAGGA X X 3 3 0 TACAGGGTC CTCGGT GAGTGAGGA X X 3 3 0 AGCAGAGGT GCTGA GAGTGAGGA X X 3 3 0 GGAAGAGTC CAGGG GAGTGAGGA X X 3 3 0 GGAAGAGTC CAGGG GAGTGAGGA X X 3 3 0 AGTGGGGTC TGTTGG GAGTGAGGA X X 3 3 0 ATGAGGGTC ACTGAG GAGTGAGGA X X 3 3 0 GTCAGAGTC CTAGG GAGTGAGGA X X 3 3 0 GCCAGGGTC TGGGAG GAGTGAGGA X X 3 3 0 AGCAACTCC ATCTT GAGTGAGGA X X 3 3 0 AGGGGAGTC GACAG GAGTGAGGA X X 3 3 0 GTCAGGGTC ATCAG GAGTGAGGA X X 3 3 0 GTCAGGGTC ATCAG GAGTGAGGA X X 3 3 0 AGCATAGTA GTTAA GAGTGAGGA X X 3 3 0 GTCAGAGTC CAAAA GAGTGAGGA X X 3 3 0 GGCAGTGTT ACAAA GAGTGAGGA X X 3 3 0 GCCATCGTC ACCCA GAGTGAGGA X X 3 3 0 CTCAGTGTC GAGAGA GAGTGAGGA X X 3 3 0 GGAAGAGTC AAGGGA GAGTGAGGA X X 3 3 0 AGCAACTCC AGAAGA GAGTGAGGA X X 3 3 0 AGCCTCGGC GGCCCT GAGTGAGGA X X 3 3 0 GACAGGGTC ACTTTA GAGTGAGGA X X 3 3 0 AGAATAGTC CTGGG GAGTGAGGA X X 3 3 0 AGTAGAGTA GTAAAG GAGTGAGGA X X 3 3 0 GGGAGGGTC GGTCAG GAGTGAGGA X X 3 3 0 AACAGGGTT ATCCA GAGTGAGGA X X 3 3 0 GCCAGGGTC ACCCA GAGTGAGGA X X 3 3 0 GGAAGAGTC TTACCT GAGTGAGGA X X 3 3 0 AGTGGAGTC ACCGTA GAGTGAGGA X X 3 3 0 GCCAGAGTC ACCCTT GAGTGAGGA X X 3 3 0 GGCAGTGTA ACTTAA GAGTGAGGA X X 3 3 0 CTCAGTGTC GTTGT GAGTGAGGA X X 3 3 0 AGATGGGTC TACAGA GAGTGAGGA X X 3 3 0 GCCAGAGTC TGAGTG GAGTGAGGA X X 3 3 0 AGTAGGGTT TGAAT GAGTGAGGA X X 3 3 0 CACTGCGTC CTTGGT GAGTGAGGA X X 3 3 0 AACTGGGTC CCTGAG GAGTGAGGA X X 3 3 0 AGTAACATC AGTAGT GAGTGAGGA X X 3 3 0 GACAGAGTC CACAGA GAGTGAGGA X X 3 3 0 ATCAGGTTC CAATA GAGTGAGGA X X 3 3 0 AGCATGGTA GTGGG GAGTGAGGA X X 3 3 0 AGCAACTGC CCTTCT GAGTGAGGA X X 3 3 0 GGCTGAGTC TTGCAG GAGTGAGGA X X 3 3 0 AGCAGCCCA GGGGGT GAGTGAGGA X X 3 3 0 AGCAAAGTG TCAAT GAGTGAGGA X X 3 3 0 AGAAAAGTC CACAGG GAGTGAGGA X X 3 3 0 AACAACTTC TCCTG GAGTGAGGA X X 3 3 0 TGCGGAGTC CCTGGG GAGTGAGGA X X 3 3 0 AGAATGGTC TCTGAT GAGTGAGGA X X 3 3 0 AGCAGCAGA ACAACT GAGTGAGGA X X 3 3 0 AGCAGCAGA TATTG GAGTGAGGA X X 3 3 0 AGTTGCTTC TTCTAA GAGTGAGGA X X 3 3 0 GACAGGGTC CTGGA GAGTGAGGA X X 3 3 0 GGAAGAGTC CGGGG GAGTGAGGA X X 3 3 0 GGAAGAGTC CAAAG GAGTGAGGA X X 3 3 0 AGGGGGGTC AAGAGT GAGTGAGGA X X 3 3 0 AACAACTTC CATGT GAGTGAGGA X X 3 3 0 ACCAAGGTC AGCAGG GAGTGAGGA X X 3 3 0 GGCCACGTC GCACAG GAGTGAGGA X X 3 3 0 AGCAAGGTT AGGAAG GAGTGAGGA X X 3 3 0 AGTAGGGTT GGAGGG GAGTGAGGA X X 4 0 4 AGCAGCGTC ACAAAA TAGCAAGGT X X 4 0 4 AGCAGCGTC AAGGG GAGACAAGT X X 4 0 4 AGCAGCGTC CGTCCC GAGAGGCGC X X 4 1 3 AGCAGCGGC CTAGC GGGTGAGTC X X 4 1 3 AGCAGCGTT GCTAT GAGAAAGGT X X 4 1 3 AGCAACGTC ATGTGC TGGGGAGGA X X 4 1 3 AGCAGCGGC CGGAG AAGTGTGGG X X 4 1 3 AGCAACGTC TGTTT GTGTAAGGC X X 4 1 3 AGCAACGTC ACCTG GAGTCACGC X X 4 1 3 AGCAGTGTC ATGATG GTGTGTGAA X X 4 1 3 AGCAGCGGC CACATA GTGTGTGAA X X 4 1 3 AGCAACGTC CAGTCC AAGTGTGGC X X 4 1 3 AGCAACGTC GGATGC AGGTGAGCA X X 4 1 3 ATCAGCGTC CAGATG GTGTGAGTC X X 4 1 3 AGCAACGTC CTTAC TAGTGAATA X X 4 1 3 AGCAACGTC GTGAC GTGCGATGA X X 4 1 3 AGCAGTGTC TGTCTG GAGTGTTGC X X 4 1 3 AGCAGCGTT GTTTTG ATGTGAGGC X X 4 1 3 AGCAACGTC TGTGT GAGTGACAG X X 4 1 3 AGCACCGTC TGCCG GTGTGCGGT X X 4 1 3 AGCAACGTC CAGTCC AAGTGTGGC X X 4 2 2 AGCATTGTC TTGTGG GAGTAAGGC X X 4 2 2 AGCAGCGAT GGGGTT GAGTGAGAC X X 4 2 2 AGCTGTGTC ATCCAT GAGTGAGTC X X 4 2 2 AGCATGGTC AAGTTC TAGTGAGGG X X 4 2 2 AGCATGGTC AAGTTC TAGTGAGGG X X 4 2 2 AGCATCTTC ATATG GAGTGAGAG X X 4 2 2 AGCATGGTC AGGTTC TAGTGAGGG X X 4 2 2 AGCATAGTC AAGGG GAGTGAGAG X X 4 2 2 AGCATGGTC TCTTTC TAGTGAGGG X X 4 2 2 AGCATGGTC AGGTTC TAGTGAGGG X X 4 2 2 AGCATAGTC TTTATT GAGTGAGAG X X 4 2 2 AGCAAAGTC CTGAAG GAGTGAGAG X X 4 2 2 AGCAGCGCA AAGCAC GTGTGAGGC X X 4 2 2 ATCAACGTC TGGAC TAGTGAGGG X X 4 2 2 AGTAGTGTC CACAG AAGTGAGGG X X 4 2 2 AGCAAAGTC CCTTG GAGTGAGTG X X 4 2 2 AGCCACGTC TATGCT TTGTGAGGA X X 4 2 2 AGCATGGTC GGGTTC TAGTGAGGG X X 4 2 2 AGCAGAGTT GGGAAA AAGTGAGGG X X 4 2 2 AGCATTGTC ACTGT GAGTGAGAG X X 4 2 2 AGCATGGTC AGGTTC TAGTGAGGG X X 4 2 2 AGCATGGTC AGGTTC TAGTGAGGG X X 4 2 2 AGCATGGTC TAGCA GAGTGAGTC X X 4 2 2 AGCTGTGTC ATCCAT GAGTGAGTC X X 4 2 2 AGTAGAGTC TGGGTG GAGTGAGAC X X 4 2 2 AGCATGGTC AGGTTC TAGTGAGGG X X 4 2 2 AGCTGTGTC CAGGAG GAGTGAGTC X X 4 2 2 AGCAACTTC TGATC TAGTGAGGT X X 4 2 2 AGCTGAGTC AACCT GAGTAAGGG X X 4 2 2 AGTAGGGTC ATCAG AAGTGAGGT X X 4 2 2 AGCTGTGTC ACCTT GAGTGAGTC X X 4 2 2 AGCAACATC TGGAA GAGTGAGAG X X 4 2 2 AGCATCGTG TTTGA AAGTGAGGC X X 4 2 2 AGCATGGTC AGGTTC TAGTGAGGG X X 4 2 2 AGCAACTTC AGGGG AAGTGAGGG X X 4 2 2 AGCATGGTC AGATTA TAGTGAGGG X X 4 2 2 AGCATGGTC CGTGTC TAGTGAGGG X X 4 2 2 AGCAAGGTC ACCTGA GAGTGAGAG X X 4 2 2 AGCATGGTC AAGTTC TAGTGAGGG X X 4 2 2 AGCAGGGTA TAGGG GAGTGAGAT X X 4 2 2 GGCAGAGTC CAAGCA GAGTGAGAG X X 4 2 2 AGTAACGTC AAAGGT GAGTGAAAA X X 4 2 2 AGCATGGTC AATTTC TAGTGAGGG X X 4 2 2 AGCAGTGTG GAGTG GAGTGAGAG X X 4 2 2 AGCACCATC CCCAT GAGTGAGTC X X 4 2 2 AGCAACGTG AGACAG TAGTGAGAA X X 4 2 2 AGCAACGGC CCTGGG CAGTGAGGG X X 4 2 2 AGTAGAGTC ATGGA GAGTGAGAG X X 4 2 2 GGCACCGTC GCTGA GAGTGAGTC X X 4 2 2 AGCATGGTC AGGTTC TAGTGAGGG X X 4 2 2 AGCATAGTC AGGTTC TAGTGAGGG X X 4 2 2 AGTAACGTC TCCCT GAGTGTGGG X X 4 3 1 AGCATAGTG GTTAG GAGTGAGGG X X 4 3 1 ATCAGGGTG GGTAG GAGTGAGGC X X 4 3 1 TACAGAGTC TCCAG GAGTGAGGG X X 4 3 1 ATGAGGGTC TCATA GAGTGAGGT X X 4 3 1 AGCAAATTC TTCAG GAGTGAGGT X X 4 3 1 AGCAAAGTG CTCAAA GAGTGAGGC X X 4 3 1 ATAAGTGTC ATTGAA GAGTGAGGC X X 4 3 1 AGTAGTCTC TTGAT GAGTGAGGG X X 4 3 1 CGCAGCAAC AGCGGT GAGTGAGGG X X 4 3 1 AGCAATGTG TGCTT GAGTGAGGC X X 4 3 1 ACCAAAGTC TTTGAT GAGTGAGGG X X 4 3 1 AGTAGTGTT TCAAGA GAGTGAGGC X X 4 3 1 AGCATAGTG GGGTAG GAGTGAGGG X X 4 3 1 ATCACCATC CTAAGT GAGTGAGGG X X 4 3 1 AGAATCGTT TGAAA GAGTGAGGG X X 4 3 1 AGTAACATC GGAAAA GAGTGAGGT X X 4 3 1 AGGACAGTC AGTTG GAGTGAGGT X X 4 3 1 GGCAGTGTT GACAG GAGTGAGGC X X 4 3 1 AGTTGTGTC GTTTT GAGTGAGGT X X 4 3 1 CCCACCGTC CCGCCC GAGTGAGGG X X 4 3 1 AGTACCGGC TTCACA GAGTGAGGT X X 4 3 1 AGCAACTTT GGAATG GAGTGAGGG X X 4 3 1 AGCAAGGGC AGTGA GAGTGAGGC X X 4 3 1 GTCAGGGTC ATAAGA GAGTGAGGC X X 4 3 1 AGGAAAGTC TAACA GAGTGAGGT X X 4 3 1 CACAGTGTC AGGCT GAGTGAGGT X X 4 3 1 GTCAGTGTC CAAGAA GAGTGAGGT X X 4 3 1 ATCACCATC CAGAGA GAGTGAGGG X X 4 3 1 ATCAACATC TTTGG GAGTGAGGC X X 4 3 1 CCGAGCGTC TGAAA GAGTGAGGT X X 4 3 1 AGCACAGTG AGCACT GAGTGAGGG X X 4 3 1 AACATTGTC TAAGG GAGTGAGGT X X 4 3 1 AACATTGTC TAAGG GAGTGAGGT X X 4 3 1 AACATTGTC TAAGG GAGTGAGGT X X 4 3 1 AGTACCGGC ATCCAT GAGTGAGGT X X 4 3 1 AGTACAGTC TCTGTT GAGTGAGAA X X 4 3 1 AACAACATC ACGGG GAGTGAGGT X X 4 3 1 TCCCGCGTC CGGGAA GAGTGAGGT X X 4 3 1 AGGGGAGTC AGATGC GAGTGAGGG X X 4 3 1 AGTAGCTGC GGCCA GAGTGAGGC X X 4 3 1 GGAAGGGTC AGTGC GAGTGAGGG X X 4 3 1 GGAAGGGTC AGTGC GAGTGAGGG X X 4 3 1 GGAAGGGTC AGTGC GAGTGAGGG X X 4 3 1 GGAAGGGTC AGTGC GAGTGAGGG X X 4 3 1 GGAAGGGTC AGTGC GAGTGAGGG X X 4 3 1 GGAAGGGTC AGTGC GAGTGAGGG X X 4 3 1 CTCAGTGTC TCCCA GAGTGAGGC X X 4 3 1 AGTAAAGTC ACAAG GAGTGAGGT X X 4 3 1 AACGGGGTC TGGGA GAGTGAGGT X X 4 3 1 GGGAGGGTC CCCAT GAGTGAGGG X X 4 3 1 GGCAGGGTT AAGATT GAGTGAGGC X X 4 3 1 AGGGGAGTC TGAGGG GAGTGAGGG X X 4 3 1 AACAATGTC ATGTT GAGTGAGGG X X 4 3 1 AGCTTGGTC TGGCT GAGTGAGGT X X 4 3 1 ATGAGGGTC TCATA GAGTGAGGT X X 4 3 1 GCCAGTGTC TCTTAG GAGTGAGGT X X 4 3 1 ATCACAGTC TCTGG GAGTGAGGC X X 4 3 1 GACAGGGTC TTAAT GAGTGAGGC X X 4 3 1 AGCCTTGTC GTAACT GAGTGAGGT X X 4 3 1 GGCAGCGGT GTTCA GAGTGAGGG X X 4 3 1 TCCAGTGTC TATGG GAGTGAGGC X X 4 3 1 AGCAGCTGT GATGT GAGTGAGGG X X 4 3 1 AGCAGCTCA CATGG GAGTGAGGT X X 4 3 1 GGCAACGGC ACACA GAGGGAGGA X X 4 3 1 AGCTGAGTT AAGCA GAGTGAGGT X X 4 3 1 AGCAGCACA AAGCTG GAGTGAGGG X X 4 3 1 AGCAACCTT GAGAT GAGTGAGGC X X 4 3 1 AGCAAATTC GGGCCC GAGTGAGGT X X 4 3 1 AGACGGGTC GGCCC GAGTGAGGT X X 4 3 1 GCCAGAGTC TGCACA GAGTGAGGG X X 4 3 1 AGCAACAGC ATTTGG GAGTGAGGG X X 4 3 1 AACCGAGTC ACTCAA GAGTGAGGG X X 4 3 1 AGCAGCTCA CCAGCA GAGTGAGGT X X 4 3 1 GGAAGGGTC CTGTGT GAGTGAGGG X X 4 3 1 AGAACGGTC CAGCA GAGTGAGGC X X 4 3 1 AGCAAGGTA AGGAA AAGTGAGGA X X 4 3 1 AGAATGGTC AGTGGG GAGTGAGGG X X 4 3 1 AGAATGGTC CAAAT GAGTGAGGG X X 4 3 1 AGCAAGGGC TCCGT GAGTGAGGG X X 4 3 1 TGCTGAGTC TCCATG GAGTGAGGG X X 4 3 1 AGCATTGTT TCTGGG GAGTGAGGG X X 4 3 1 AGCATTGTG GTGAG GAGTGAGGG X X 4 3 1 GCTAGCGTC CATGG GAGTGAGGC X X 4 3 1 AGCAACTTT CCACTG GAGTGAGGC X X 4 3 1 AGTAGGGTT GGTGG GAGTGAGGG X X 4 3 1 GGCAGTGTT TCCCAG GAGTGAGGC X X 4 3 1 AACTGAGTC TCTGG GAGTGAGGT X X 4 3 1 AGCATTGTG ATGAG GAGTGAGGG X X 4 3 1 AGCAAGGTT TATGT GAGTGAGCA X X 4 3 1 GGCAACGTT TGTAT GAGTGAGGT X X 4 3 1 AACAACCTC GCCTAT GAGTGAGGG X X 4 3 1 AGGGACGTC CAAGG GAGTGAGGG X X 4 3 1 TCCAGTGTC ACATCA GAGTGAGGC X X 4 3 1 AGCATGGTT GGAGTA GAGTGAGGG X X 4 3 1 AATAGGGTC AAAAT GAGTGAGGT X X 4 3 1 AGTATAGTC TTTAGG GAGTGAGGC X X 4 3 1 TGCAATGTC CTTGG GAGTGAGGC X X 4 3 1 AGCTACATC TACAGG GAGTGAGGG X X 4 3 1 AGCAAAGTA AAGAGA GAGTGAGGC X X 4 4 0 CACCCCGTC TACCTG GAGTGAGGA X X 4 4 0 AGGCACGTT AGGCA GAGTGAGGA X X 4 4 0 CACCCCGTC GACGTC GAGTGAGGA X X 4 4 0 GCAAGAGTC TGGCT GAGTGAGGA X X 4 4 0 AGTGCAGTC CCTTA GAGTGAGGA X X 4 4 0 ATCCACGTT ATGCTG GAGTGAGGA X X 4 4 0 ATCCACGTT TTGGG GAGTGAGGA X X 3 1 2 AGCAGCTTC TGCCAT GAGTGAAGT X X 3 1 2 AGCAGGGTC TGCAGT GAGAGAGGC X X 3 1 2 AGCAGCTTC CAGGA GAGTGAAGT X X 3 1 2 AGCAGGGTC TGTTTT GAGTGAGTT X X 4 3 1 AGCAACTGC ATTTT GAGTGAGGG X X 4 3 1 AGCAACTGC ATCTT GAGTGAGGG X X 3 1 2 AGCAGCTTC CCAAAA ATGTGAGGA X X 3 3 0 AGGTGCCTC CCCATG GAGTGAGGA X X 5 3 2 AGCTCAGTC CACAG GAGTGAGTC X X 2 1 1 AGCAGCGTG CAGAA GAGAGAGGA X 2 1 1 AGCAGCGTG GATGGA GAGAGAGGA X 2 1 1 AGCAGCGTG GATGGA GAGAGAGGA X 2 1 1 AGCAGCGTG GATGGA GAGAGAGGA X 2 1 1 AGCAGCCTC TGCCAG GGGTGAGGA X 2 1 1 AGCAGCCTC CCATA GAGGGAGGA X 2 1 1 AGGAGCGTC CCTTGG GAGTGATGA X 2 1 1 AGCAGCGAC AGCCA GAGTGACGA X 2 1 1 AGCTGCGTC CTGTA GCGTGAGGA X 2 1 1 AGCAGGGTC TGCCT GAGTCAGGA X 2 1 1 AGCAGCATC TGGGA GAATGAGGA X 2 1 1 AGGAGCGTC CAGTGC GACTGAGGA X 2 1 1 AGCAGCGTG GATGGA GAGAGAGGA X 2 1 1 AGCAGCGTG GATGGA GAGAGAGGA X 2 1 1 AGCAGCATC ACAGAC GCGTGAGGA X 2 1 1 ACCAGCGTC TGCTTT GGGTGAGGA X 2 1 1 AGCAGGGTC ATTGA GAATGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AGGAGCGAC GGGGG GAGTGAGGA X 2 2 0 AACAGCCTC CTTCC GAGTGAGGA X 2 2 0 AGAAGCATC CGAAGG GAGTGAGGA X 2 2 0 AGAAGCCTC CATTCC GAGTGAGGA X 3 0 3 AGCAGCGTC AGGGG AAATTAGGA X 3 0 3 AGCAGCGTC TTGGAA GACCGAGGT X 3 0 3 AGCAGCGTC CTGTG GCGTGGCGA X 3 0 3 AGCAGCGTC TCAGCG GGTGGAGGA X 3 0 3 AGCAGCGTC CGCCGA GAGTCAGCC X 3 0 3 AGCAGCGTC AGGGAG AAGTCAGGT X 3 0 3 AGCAGCGTC AACAGT GCCTGATGA X 3 0 3 AGCAGCGTC AGTAGA GACAGAGAA X 3 0 3 AGCAGCGTC GGGTGG GTTTGGGGA X 3 0 3 AGCAGCGTC TCCGAA GAGACAGCA X 3 0 3 AGCAGCGTC CCGAG GAGCTGGGA X 3 0 3 AGCAGCGTC CGGCC GCGGCAGGA X 3 0 3 AGCAGCGTC CGGCC GCGGCAGGA X 3 0 3 AGCAGCGTC ACTCCC AAGCGAGTA X 3 0 3 AGCAGCGTC CCCTG CAGAGAGCA X 3 0 3 AGCAGCGTC TCTCTG GGCTGGGGA X 3 0 3 AGCAGCGTC CAGGAG GGCTGGGGA X 3 0 3 AGCAGCGTC AGGGTG GAGTCATGT X 3 0 3 AGCAGCGTC TGATTG GCGGGGGGA X 3 0 3 AGCAGCGTC TGGGG AATTGGGGA X 3 0 3 AGCAGCGTC CGCCGA GAGTCAGCC X 3 1 2 AGCAGTGTC AGTTG GCGGGAGGA X 3 1 2 AGCAGAGTC CAAAAG GGGTGAGGC X 3 1 2 ATCAGCGTC CAGAG GAGTGAACA X 3 1 2 AGCAGAGTC TCAGAG GAGTGAAGC X 3 1 2 AACAGCGTC CTGGGA GAGTGTGCA X 3 1 2 TGCAGCGTC TTCTT TAGTGAGCA X 3 1 2 AGCAGCTTC CAACAA TAGTAAGGA X 3 1 2 AGCAGTGTC CCCTAT AAGTGAGAA X 3 1 2 AGCAGCATC AATCT GAGTGTGGG X 3 1 2 AGCAGTGTC AACAT CAGTGAGAA X 3 1 2 AGCAGCTTC TCCCA GGGTGAGGC X 3 1 2 AGCAGAGTC AGGCA GGGTGAGGC X 3 1 2 AGCAGGGTC TGCAGG GAGTGTGGT X 3 1 2 AGCTGCGTC CTCTA GAGGGAGGG X 3 1 2 AGCAGCGTA CCTGG GTGTGAGAA X 3 1 2 AGCAGCCTC AGAAAT AGGTGAGGA X 3 1 2 AGCAGCGTT CCTCT CAGTGATGA X 3 1 2 AGCAGCCTC TGGAGG GAGGGAGGG X 3 1 2 AGCAGTGTC AGATGG TGGTGAGGA X 3 1 2 AGCAGTGTC TTGTTA AAGTGAAGA X 3 1 2 AGCAGCATC TGGGTA GAGTGAAGG X 3 1 2 AGCAGCATC CTCCT GGGTAAGGA X 3 1 2 AGCAGGGTC CCTCT GAGTGGGGC X 3 1 2 ATCAGCGTC TTTCTT GAGTGATAA X 3 1 2 AGCAGCATC CTCCT GGGTAAGGA X 3 1 2 AGCAGCATC CTCCT GGGTAAGGA X 3 1 2 AGCAGCATC CTCCT GGGTAAGGA X 3 1 2 AGCAGCATC CTCCT GGGTAAGGA X 3 1 2 AGCAGTGTC TTAGGG GAATGAGGC X 3 1 2 AGCAGCTTC CAGGCA GAGGGAGAA X 3 1 2 AGCAGCGTG CTGCGA GAGTGTGAA X 3 1 2 AGTAGCGTC CTTGG GATTGAAGA X 3 1 2 AGCAGCTTC CAGACT GAGGGAGAA X 3 1 2 AGCAGCGTG GAGGA GAGAGAGGC X 3 1 2 ATCAGCGTC ATCCA GAAGGAGGA X 3 1 2 AGCAGCATC AAAGAG GAGAGAGGG X 3 1 2 AGCAGTGTC TTCCAT GAGTGGGTA X 3 1 2 AGCAGCGAC TGTAG AAATGAGGA X 3 1 2 AGCAGTGTC GATACA TGGTGAGGA X 3 1 2 AGCAGCGTG GAGAG GAGGAAGGA X 3 1 2 AGCAGCTTC ACTGT GACTGAAGA X 3 1 2 AGCAGAGTC CTCTT TTGTGAGGA X 3 1 2 AGCAGCTTC TCCAG CAGTGATGA X 3 1 2 AGCAGTGTC ATACT AAGGGAGGA X 3 1 2 AGCCGCGTC TCCAA GAGTCAGTA X 3 1 2 TGCAGCGTC AAATTG GAGTAAGGG X 3 1 2 AGCAGCATC AGAGGT GTGTGAGAA X 3 1 2 AGCAGCGTG TTCATG GAGTGCGGC X 3 1 2 AGCAGTGTC CTTTG CAGTGAGAA X 3 1 2 AGCAGCGCC TCTCA GAGTGAACA X 3 1 2 AGCAGCATC TTGGG AACTGAGGA X 3 1 2 AGCAGCCTC TTTTTG GAGGGAGGG X 3 1 2 GGCAGCGTC GCAGG GAGTGGGAA X 3 1 2 AGCAGCCTC GGAAAC AAGTGAGGG X 3 1 2 AGCAGAGTC TGATAT GAGTGAGCT X 3 1 2 TGCAGCGTC AGCAT GAGTGGGGC X 3 1 2 AGCAGGGTC TGGAGG GAGACAGGA X 3 1 2 AGCAGAGTC ACGAGA GAATGGGGA X 3 1 2 AGCAGGGTC CTGCA GGGTGAGGC X 3 1 2 AGCAGCCTC AGGGAT GAGGGAGGT X 3 1 2 AGCAGCGGC ATCGG GGGCGAGGA X 3 1 2 AGCAGGGTC ATCACA GAGGGAAGA X 3 1 2 AGCAGTGTC TGGTGT GAGGGAGCA X 3 1 2 AGCAGCGGC TGGGGG GAGGCAGGA X 3 1 2 AGCAGCATC CCTGGA GAGGGAGAA X 3 1 2 AGCAGGGTC GGTGTC TGGTGAGGA X 3 1 2 AGCAGGGTC CAGGT AAGAGAGGA X 3 1 2 AGCAGTGTC ATCTCT GAGTGGAGA X 3 1 2 AGCAGCCTC CGTCTA GAGGGAGGT X 3 1 2 AGCAGCGCC AGCCTC AAGTGAGGG X 3 1 2 AGCAGCGAC ATTGT GAGTAAGCA X 3 1 2 AGCAGCTTC CGGTG TAGTGATGA X 3 1 2 AGCAGGGTC CCAGCA GAGAAAGGA X 3 1 2 AGCAGCGAC TCCGG GAGTGCAGA X 3 1 2 AGCAGCGTG GGAAA GAGGAAGGA X 3 1 2 GGCAGCGTC TATGGA GAATGAGAA X 3 1 2 AGCAGCCTC CACACT GAGGGAGGT X 3 1 2 AGCAGCCTC CCTCTT GTGTGAGGG X 3 1 2 TGCAGCGTC GCTGA AAGTGAGAA X 3 1 2 AGCAGTGTC TTGTAT GACTGAGGT X 3 1 2 AGCAACGTC AGCAAA GTGTCAGGA X 3 1 2 AGCAGCATC AGCAG GAGTGTGAA X 3 1 2 AGCAGCCTC ATTGG GAGTGAGTG X 3 1 2 AGCAGGGTC TTGGAT GAGTTAAGA X 3 1 2 AGCAGCGGC AGACT GAGCGAGCA X 3 1 2 AGCAGGGTC CTGTTG GAGACAGGA X 3 1 2 AGCAGCATC AGCAT CAGTTAGGA X 3 1 2 AGCAGAGTC AGAAAT GAGTGAAGC X 3 1 2 AGCAGCGCC CACCCT TGGTGAGGA X 3 1 2 AGCAGCGGC TGATG GAGGCAGGA X 3 1 2 AGCAGCCTC GCTTTG AGGTGAGGA X 3 1 2 AGCATCGTC ATCCTA GAGTCAGCA X 3 1 2 GGCAGCGTC GGGCA GAGGGAGAA X 3 1 2 AGCAGCCTC ATCCT GTGAGAGGA X 3 1 2 AGCAGTGTC TTCCAT GAGTGGGTA X 3 1 2 GGCAGCGTC CAATCT CAGTGAGAA X 3 1 2 AGCAGTGTC ACCTCT GAGTGGGTA X 3 1 2 AGCAGCATC TATAGC GACTGAGGT X 3 1 2 AGCAGTGTC TGGTTT GGGGGAGGA X 3 1 2 AGCAGAGTC GGAGT GAGAGAGGG X 3 1 2 AGTAGCGTC TAGGC AAGTGAGCA X 3 1 2 AGCAGCCTC TACAT GAGTGAGAC X 3 1 2 AGCAGTGTC AATAA GAGAGTGGA X 3 1 2 AGCAGCGTT TCTCA AAGTGCGGA X 3 1 2 AGCAGCGAC TGTGA AAGTGAGAA X 3 1 2 AGCAGAGTC CCTGT GAGTGAAGG X 3 1 2 GGCAGCGTC CTTTC CAGCGAGGA X 3 1 2 AGCAGGGTC AATGTC TGGTGAGGA X 3 1 2 AGCAGCATC AGGCT GAGTGTGGT X 3 1 2 AGCAGTGTC TCGTT AGGTGAGGA X 3 1 2 AGCAGGGTC AGCAAA GAATGAGGC X 3 1 2 AGCAGAGTC ACAAA GAATGAGTA X 3 1 2 AGCAGCGTG GGGCTG GAGGGAGAA X 3 1 2 AGCAGCGTG TTCATG GAGTGCGGC X 3 1 2 AGCAGCATC TAACAG GAGGGAGGG X 3 1 2 AGCAGCCTC CTAGG GAGGGAGGG X 3 1 2 AGCAGCTTC TGAGC TAGTGAAGA X 3 1 2 ATCAGCGTC TACTAA GAGAGTGGA X 3 1 2 AGCAGCATC ACCTGC GAGGGAGGG X 3 1 2 AGCAGCATC GAGTT GGGTGAGGT X 3 1 2 TGCAGCGTC CAAGCT CAGTGAGGC X 3 1 2 AGCAGCTTC ATTTT GAATGAGGG X 3 1 2 AGCAGCCTC TTTTGG GAGTGGGGG X 3 1 2 AGCAGCGCC TCCCA GAGTGGGGC X 3 1 2 AGCAGGGTC CCCCA GAGAAAGGA X 3 1 2 AGCAGCCTC CCGGA GAGGGAGGG X 3 1 2 GGCAGCGTC GGGTGG GAGAGAGAA X 3 1 2 AGCAGAGTC TACCTT GAGTGAAAA X 3 1 2 AGCAGCGAC CCAAG GAGTAAGAA X 3 1 2 AGCAGTGTC TTTAGA AAGTGAGCA X 3 1 2 AGCAGGGTC GGGCC TGGTGAGGA X 3 1 2 AGCAGCGGC TGAATC CTGTGAGGA X 3 1 2 TGCAGCGTC TGGCAT GAGTGGGGC X 3 1 2 AGAAGCGTC ATGCT GAGTGAAAA X 3 1 2 AGCAGGGTC CAGGGA GAGGGAAGA X 3 1 2 AGCAGCATC CCTGT GAGTGAGTG X 3 1 2 AGTAGCGTC AATGAT AAGTGTGGA X 3 1 2 AGCAGGGTC CAGGT AAGAGAGGA X 3 1 2 AGCAGGGTC CAGGT AAGAGAGGA X 3 1 2 AGCAGGGTC CAGGT AAGAGAGGA X 3 2 1 AGCAACCTC ACCCCA GAGAGAGGA X 3 2 1 AGCAACGTG TGTTGG GAGAGAGGA X 3 2 1 ATCAGGGTC AGGTTT TAGTGAGGA X 3 2 1 AGCAAAGTC TGTAT GAGTGAGCA X 3 2 1 AGCAGTGTA AAGGAG TAGTGAGGA X 3 2 1 AGCAGAGTA AAGCAG GTGTGAGGA X 3 2 1 AGCAGCCTG GGAGA GAGTGAGGG X 3 2 1 AGCAACCTC CTGGGT GAGAGAGGA X 3 2 1 AACAGCTTC AGTACA CAGTGAGGA X 3 2 1 AGTAGTGTC AATGAA GAGTGAAGA X 3 2 1 ATCAGGGTC TAGGGA GAGTGTGGA X 3 2 1 GGCAGGGTC CCCGG GAGGGAGGA X 3 2 1 AGCTGGGTC TGAAGG GTGTGAGGA X 3 2 1 AGCTGGGTC CTCAG GAGAGAGGA X 3 2 1 AGCAGCTCC AGGGCC GAGTGAGAA X 3 2 1 AGCAACATC CGCTCT GAGTGGGGA X 3 2 1 AACAGCTTC ACAGG CAGTGAGGA X 3 2 1 AGCAGCGCC CAACAC CAGTGAGGA X 3 2 1 AGCAGGGGC AGTGG GAGTGAGTA X 3 2 1 AGCATGGTC TGGTT GGGTGAGGA X 3 2 1 GGCAGCGTG CTCTGA GAGAGAGGA X 3 2 1 AGCAGAGCC CCCTG GAGTGAGGG X 3 2 1 AGCACCGTG CTTCAA AAGTGAGGA X 3 2 1 CCCAGCGTC AGCAG GAGTCAGGA X 3 2 1 AGGAGCGTG GACACA GAGTGAGGT X 3 2 1 AGCCGAGTC TGTCCC GAGTGTGGA X 3 2 1 AGTAGAGTC TCTGTT GAGTGAGTA X 3 2 1 ACCAGGGTC ATGGC AAGTGAGGA X 3 2 1 TGCAGGGTC AGATTG AAGTGAGGA X 3 2 1 AGCAGCGGG GAGAGA GAGCGAGGA X 3 2 1 TGCAGCGCC GAGGT GAGTGAGGG X 3 2 1 AGTAGAGTC TGGCT GAGGGAGGA X 3 2 1 TGCAGCGCC GAGGT GAGTGAGGG X 3 2 1 AGTAGGGTC ACACTA GAGTGAAGA X 3 2 1 TGCAGCGCC GAGGT GAGTGAGGG X 3 2 1 TGCAGCGCC GAGGT GAGTGAGGG X 3 2 1 TGCAGCGCC GAGGT GAGTGAGGG X 3 2 1 TGCAGCGCC GAGGT GAGTGAGGG X 3 2 1 TGCAGCGCC GAGGT GAGTGAGGG X 3 2 1 TGCAGCGCC GAGGT GAGTGAGGG X 3 2 1 AGCAGGGTA AAGCAA GAGTGAGAA X 3 2 1 AGCAGCGGG GACCGG GAGCGAGGA X 3 2 1 AGCAGGTTC AGTGTC TAGTGAGGA X 3 2 1 GGCATCGTC TGCAGT AAGTGAGGA X 3 2 1 AATAGCGTC AGCCCC AAGTGAGGA X 3 2 1 AGCAGCATG GTATG GAGGGAGGA X 3 2 1 AGCAGCCTG CTGCA GAGTGAGGG X 3 2 1 GGCAGCGTG GTGGT GAGAGAGGA X 3 2 1 AGCAGAGTT GGTGTC TAGTGAGGA X 3 2 1 AACAGAGTC GGGAA GAGTAAGGA X 3 2 1 AACAGCGGC GTCCT GAGTGTGGA X 3 2 1 AGCAGGGTG TGAGA GAGGGAGGA X 3 2 1 AGCTGCATC AAACT TAGTGAGGA X 3 2 1 GGCAGGGTC TCCCG GAGGGAGGA X 3 2 1 AGCAGCTTT TCAGA GAGTGAAGA X 3 2 1 AGCAGGGCC CTGCT GAGTGAGGG X 3 2 1 AGCAGGGCC CTGCT GAGTGAGGG X 3 2 1 GGCAGCGTT GGGAT GTGTGAGGA X 3 2 1 AACAGAGTC ACAGT GAGTAAGGA X 3 2 1 AGCAGGGCC GGGCA GAGTGAGGG X 3 2 1 GGGAGCGTC TGCCC CAGTGAGGA X 3 2 1 ATCAGTGTC TAAAAT GGGTGAGGA X 3 2 1 AGCGGCTTC TGCCT GAGTGAGGG X 3 2 1 AGCAATGTC TGCCTT GGGTGAGGA X 3 2 1 AGCAAAGTC ACCAG GAGTGAGCA X 3 2 1 AGCAATGTC AATCAG GAGAGAGGA X 3 2 1 AGCAGGGTG GAAAG GAATGAGGA X 3 2 1 ACCAGCCTC CTGAGG GAGTGAGGG X 3 2 1 AGAAGCGGC GTTGT AAGTGAGGA X 3 2 1 AGCAGTGTG GTAGA CAGTGAGGA X 3 2 1 AGCAATGTC AGTCT GAGTTAGGA X 3 2 1 AGCAGGGTG TTGGAG GAATGAGGA X 3 2 1 AGCAGCATG GAAAA GAGGGAGGA X 3 2 1 AGCAGCTTT GTAGA GAGTGAAGA X 3 2 1 AGCAAGGTC TGGGA GAGTCAGGA X 3 2 1 AGCAGCCTG CCAAG GAGTGAGGG X 3 2 1 AGCAGTGGC TAAGA GAGTGAGCA X 3 2 1 AACAGCGTG TGTGA AAGTGAGGA X 3 2 1 AGCATCCTC TATGCT GTGTGAGGA X 3 2 1 AGCAGAGCC ATGAAG GAGTGAGGC X 3 2 1 AGCAGCCGC CTGAG CAGTGAGGA X 3 2 1 AGCAGCGAG GGAGG AAGTGAGGA X 3 2 1 AGCCGGGTC TTCCG AAGTGAGGA X 3 2 1 AGCCTCGTC CCCAGA GAGGGAGGA X 3 2 1 AGGAGAGTC CCATGA GAGTGAGAA X 3 2 1 AGCAATGTC AGATAG GGGTGAGGA X 3 2 1 AGCATCGGC CTCTCT GAGTGACGA X 3 2 1 AGCATCTTC AGTTG AAGTGAGGA X 3 2 1 GGCAGCGTG TATGAT GAGAGAGGA X 3 2 1 AGCAGGGTA AAGAGT GAGTGAGAA X 3 2 1 AACAGAGTC AGCCCT TAGTGAGGA X 3 2 1 AGCACAGTC CGGAT GAGTGAGCA X 3 2 1 ATTAGCGTC ACTTAG AAGTGAGGA X 3 2 1 AACAGAGTC AGAGA TAGTGAGGA X 3 2 1 AGCAGCCTG GCATG GAGTGAGGG X 3 2 1 AACACCGTC ACCTGT GGGTGAGGA X 3 2 1 AGCAGCGGA AATAA GGGTGAGGA X 3 2 1 GGCAGCGTG AACCCA GAGTGAGTA X 3 2 1 AACACCGTC CTGCCA GTGTGAGGA X 3 2 1 AGCAGCGAT GTTGT AAGTGAGGA X 3 2 1 AGCAGGGTG GGAAAG GAGGGAGGA X 3 2 1 AGCTGGGTC AGAGGT GAGAGAGGA X 3 2 1 AGCAGCTCC AGGGA GAGTGAGAA X 3 2 1 AGCAATGTC TTCCTT GGGTGAGGA X 3 2 1 AGCACAGTC TGAACA GAGTGAGCA X 3 2 1 AGCAGCGGA GGATCT GGGTGAGGA X 3 2 1 AGCAGCTTT TGGGA GAGTGAGCA X 3 2 1 AGCAGCGAT TTGAAG AAGTGAGGA X 3 2 1 AGCAGCAGC ACAAA GAGTGAGTA X 3 2 1 AGGAGCGGC AGGTGA TAGTGAGGA X 3 2 1 AGCACGGTC CAAAG GAGAGAGGA X 3 2 1 AGCTGGGTC ATTCCC CAGTGAGGA X 3 2 1 AGCTGAGTC AGCCAA GTGTGAGGA X 3 2 1 AGTAGGGTC AACGTT GAGTGAAGA X 3 2 1 AGTAGAGTC AACAGT GAGTGATGA X 3 2 1 AGGAGAGTC GCTCT GAGTGAGAA X 3 2 1 AGCGCCGTC TCTGG AAGTGAGGA X 3 2 1 AGCTGTGTC CCTCCT GAGGGAGGA X 3 2 1 AGCTGCCTC CGTGGG GAGTGAGGC X 3 2 1 AGCAGCCTG CTGCA GAGTGAGGG X 3 2 1 AGCAGCCTG CTGCA GAGTGAGGG X 3 2 1 GGCAGAGTC GTGCA TAGTGAGGA X 3 2 1 AGCATTGTC AATATT GAGGGAGGA X 3 2 1 AGCAGGGTG GGTAA GAGTGAGAA X 3 2 1 GGCAGGGTC TCTGG GAGGGAGGA X 3 2 1 AGTAGAGTC CAGTA GAGTGATGA X 3 2 1 AGCAGGGCC CTGCT GAGTGAGGG X 3 2 1 AGCAAAGTC TTTAG GAGAGAGGA X 3 2 1 AGCAGTGCC CTGAA GAGTGAGAA X 3 2 1 GGCAGGGTC CGAGCC CAGTGAGGA X 3 2 1 AGCTGGGTC TGGCT GAGTGTGGA X 3 2 1 AGCAGCTTT CATGG AAGTGAGGA X 3 2 1 ATCATCGTC ATCGT GAGAGAGGA X 3 2 1 AGCCGCGTG AGGGC AAGTGAGGA X 3 2 1 AGCAGGGTG GGCAAG GAGGGAGGA X 3 2 1 AGCATGGTC AAGTTT GGGTGAGGA X 3 2 1 ATCAGAGTC AGAGA AAGTGAGGA X 3 2 1 AGCAGTGGC AGAAT AAGTGAGGA X 3 2 1 AGGAGTGTC TGCAA AAGTGAGGA X 3 2 1 TGCAGGGTC AAGCC AAGTGAGGA X 3 2 1 AGCAGGTTC AGTGTC TAGTGAGGA X 3 2 1 AGCAGCGGA AATAA GGGTGAGGA X 3 2 1 AGCAGGGTG CTCGG GAGGGAGGA X 3 2 1 AGCAACCTC CCCACA GAGGGAGGA X 3 2 1 AGCAGGGTG GGGGA GAGGGAGGA X 3 2 1 AGCAACCTC TGCTCA GAGAGAGGA X 3 2 1 TGCAGGGTC TGCGG AAGTGAGGA X 3 2 1 AGCAGGTTC AGACTG AAGTGAGGA X 3 2 1 AGCAATGTC ACCAT GAGTGTGGA X 3 2 1 AGCACGGTC CCCAAG GAGGGAGGA X 3 2 1 AGCAGCGCT CGGGC GAGGGAGGA X 3 2 1 AGCAGGGAC TGGTCA GAGTGAGGT X 3 2 1 AGCAGCCAC ACAATC CAGTGAGGA X 3 2 1 AGTAGAGTC AAGAGG GAGTGAGTA X 3 2 1 AGCCTCGTC TTGGT GAGGGAGGA X 3 2 1 GGCAGCGGC CTGGAG GGGTGAGGA X 3 2 1 AGCAGAGTT GGTTTC TAGTGAGGA X 3 2 1 AGCATCTTC ACCTG AAGTGAGGA X 3 2 1 AGCAACATC ATAAT GAGTGGGGA X 3 2 1 AGCACAGTC CCTAA GAGTGAGCA X 3 3 0 AGGAGTTTC CAGTT GAGTGAGGA X 3 3 0 GGCAGCAGC CATCA GAGTGAGGA X 3 3 0 AGCAGGTTG TTGGAG GAGTGAGGA X 3 3 0 AACAGTGCC CTGGT GAGTGAGGA X 3 3 0 TGGAGCGTG GGGGGA GAGTGAGGA X 3 3 0 TGGAGCGTG GAAGAG GAGTGAGGA X 3 3 0 AGCTGAGGC ACAGG GAGTGAGGA X 3 3 0 TGCAGGGTG GACCCA GAGTGAGGA X 3 3 0 AACAGAGTG AGGCT GAGTGAGGA X 3 3 0 AGCAACTTA TTGCT GAGTGAGGA X 3 3 0 AGCACAATC TTTTTG GAGTGAGGA X 3 3 0 TGGAGGGTC GGTGGA GAGTGAGGA X 3 3 0 AGCCGTGTG GCTACG GAGTGAGGA X 3 3 0 TGCTGCTTC TGCCGT GAGTGAGGA X 3 3 0 AACAGAGTA ACACA GAGTGAGGA X 3 3 0 ACCAACTTC ATGTA GAGTGAGGA X 3 3 0 AGGAGAGTG AGTGT GAGTGAGGA X 3 3 0 GGCAGGGTG GCGAAG GAGTGAGGA X 3 3 0 GGCAGGGTG GCCGGG GAGTGAGGA X 3 3 0 AGCAGGGCT CCTGGT GAGTGAGGA X 3 3 0 TACAGTGTC AGCAGT GAGTGAGGA X 3 3 0 ATCACCTTC TTTCAT GAGTGAGGA X 3 3 0 TTCAGTGTC TGACGG GAGTGAGGA X 3 3 0 AGCAGCTCA GGTTAG GAGTGAGGA X 3 3 0 AGGAGAGTA GGGCT GAGTGAGGA X 3 3 0 ACCTGGGTC TGAGCA GAGTGAGGA X 3 3 0 ATCAGTGTG TTTTT GAGTGAGGA X 3 3 0 TGGAGGGTC AGAGGA GAGTGAGGA X 3 3 0 GGCAGGGTG CGAGG GAGTGAGGA X 3 3 0 AGGAGAGTG AATGT GAGTGAGGA X 3 3 0 AGCAGTGCA CCCAA GAGTGAGGA X 3 3 0 AGCAGGTTG AAGACT GAGTGAGGA X 3 3 0 AGGAGAGTG AGAAGT GAGTGAGGA X 3 3 0 AGCAGCCGT AACAAA GAGTGAGGA X 3 3 0 AGCAGGGCA GGGCA GAGTGAGGA X 3 3 0 GCCAGCCTC AGGCT GAGTGAGGA X 3 3 0 AGCAGGGCT TGGTGG GAGTGAGGA X 3 3 0 AGTAGCAAC TATTA GAGTGAGGA X 3 3 0 AACAGCGGA GATTT GAGTGAGGA X 3 3 0 AGGACCATC CGAGA GAGTGAGGA X 3 3 0 AGGACCATC CCAGG GAGTGAGGA X 3 3 0 AGGACCATC CCAGG GAGTGAGGA X 3 3 0 AGGACCATC CCAGG GAGTGAGGA X 3 3 0 AGCAGGTTA ACAGG GAGTGAGGA X 3 3 0 TGCAGGGTG AGCCT GAGTGAGGA X 3 3 0 AGAAGGGTA GAAAG GAGTGAGGA X 3 3 0 AGATGCGGC CAGTA GAGTGAGGA X 3 3 0 AATAGGGTC AGGTAG GAGTGAGGA X 3 3 0 AGCAGTGAA GGTGG GAGTGAGGA X 3 3 0 AGAAACGTG GAAAA GAGTGAGGA X 3 3 0 AACAGGGAC CTTAT GAGTGAGGA X 3 3 0 AGCAAGGAC TTAAA GAGTGAGGA X 3 3 0 AGCAGATGC CCTTG GAGTGAGGA X 3 3 0 AGCAGCTGT GCATA GAGTGAGGA X 3 3 0 AGAAGGGTT TGTGCA GAGTGAGGA X 3 3 0 AACAGAGTG GTTTA GAGTGAGGA X 3 3 0 GGCAGTGGC AGTGG GAGTGAGGA X 3 3 0 AGCACCGAG CCCCT GAGTGAGGA X 3 3 0 ATCAGCATG AAATG GAGTGAGGA X 3 3 0 AGCTGTGTG ACCCT GAGTGAGGA X 3 3 0 TGCAGGGTG GGAATA GAGTGAGGA X 3 3 0 TGCAGGGTG TAGTG GAGTGAGGA X 3 3 0 AGGAGGTTC TGGGAG GAGTGAGGA X 3 3 0 AGGAATGTC CTGGTC GAGTGAGGA X 3 3 0 AGTAGCTGC CTTTGG GAGTGAGGA X 3 3 0 AGAAGGGTG GGAGGG GAGTGAGGA X 3 3 0 AGTAGCTGC CTTTGG GAGTGAGGA X 3 3 0 AGTAGCTGC CTTTGG GAGTGAGGA X 3 3 0 AGTAGCTGC CTTTGG GAGTGAGGA X 3 3 0 AGTAGCTGC CTTTGG GAGTGAGGA X 3 3 0 AGTAGCTGC CTTTGG GAGTGAGGA X 3 3 0 AGTAGCTGC CTTTGG GAGTGAGGA X 3 3 0 AGTAGCTGC CTTTGG GAGTGAGGA X 3 3 0 AGTAGAGGC TGGAG GAGTGAGGA X 3 3 0 GGCAGCAGC AATAGA GAGTGAGGA X 3 3 0 AGCAGCACA AGCACT GAGTGAGGA X 3 3 0 TGCATCGTA AGCAT GAGTGAGGA X 3 3 0 GGCAGGGTG GGGGT GAGTGAGGA X 3 3 0 AGCAGCTGA AAGAGG GAGTGAGGA X 3 3 0 TGGAGCGTG GGAGGA GAGTGAGGA X 3 3 0 TCCAGGGTC ACTAAT GAGTGAGGA X 3 3 0 TGCAGCGAA AGGCA GAGTGAGGA X 3 3 0 AGCAGGTTG GGGAA GAGTGAGGA X 3 3 0 AGCTGAGGC TGGCA GAGTGAGGA X 3 3 0 AACAGTGGC AAATGA GAGTGAGGA X 3 3 0 GGCAGTGCC TGAAGG GAGTGAGGA X 3 3 0 GGCAGTGCC TGAAGG GAGTGAGGA X 3 3 0 GGCAGTGCC TGAAGG GAGTGAGGA X 3 3 0 AGGAGAGTA TGGAG GAGTGAGGA X 3 3 0 CGCAGCATT GCAGCG GAGTGAGGA X 3 3 0 GGAAGTGTC CTTCAA GAGTGAGGA X 3 3 0 AGCTGCATA AGGAAA GAGTGAGGA X 3 3 0 ACTAGGGTC TTTGGA GAGTGAGGA X 3 3 0 AGCTGTGTG CCAGG GAGTGAGGA X 3 3 0 ACCACTGTC AGCTGT GAGTGAGGA X 3 3 0 GGTAGCTTC TCCTG GAGTGAGGA X 3 3 0 AGCAGGGCT GGGCAG GAGTGAGGA X 3 3 0 AGCTGTGTG ATGGGA GAGTGAGGA X 3 3 0 TGAAGAGTC CAAGG GAGTGAGGA X 3 3 0 TGAAGAGTC CAAGG GAGTGAGGA X 3 3 0 ACGAGGGTC CATAG GAGTGAGGA X 3 3 0 AGAAGCGGT GGAGT GAGTGAGGA X 3 3 0 GGCAGAGTT GTACTG GAGTGAGGA X 3 3 0 AGCAGTTAC GGCAAA GAGTGAGGA X 3 3 0 TGCAGTGTG CAAGGA GAGTGAGGA X 3 3 0 CTCTGCGTC TGGAA GAGTGAGGA X 3 3 0 AGGAGAGTG AGAGAA GAGTGAGGA X 3 3 0 AGGAGAGTG AGAGAA GAGTGAGGA X 3 3 0 AATAGGGTC AGGTAG GAGTGAGGA X 4 0 4 AGCAGCGTC TCCGAA GACTCATGT X 4 0 4 AGCAGCGTC ACATAA TAGTGGAGC X 4 0 4 AGCAGCGTC CAGGA GTGGGAGTC X 4 0 4 AGCAGCGTC TGGTCT GGCGGAGGC X 4 0 4 AGCAGCGTC TTAGA AGGTGACAA X 4 0 4 AGCAGCGTC AGAGGA GGGAGACCA X 4 0 4 AGCAGCGTC ACTGGT AAGACATGA X 4 0 4 AGCAGCGTC CCTGG CATGGAGCA X 4 0 4 AGCAGCGTC TGACAG CAGTGAAAC X 4 0 4 AGCAGCGTC TCCAGG GTGTGCTGC X 4 0 4 AGCAGCGTC TCAGA GGTAGAGCA X 4 0 4 AGCAGCGTC GAGACC CATGGAGCA X 4 0 4 AGCAGCGTC GTGGC AGGGCAGGA X 4 0 4 AGCAGCGTC CTGGG GAGCGCGTC X 4 0 4 AGCAGCGTC GTTCGG GGCTGAGAT X 4 0 4 AGCAGCGTC AGGCT GTGGGAGCC X 4 0 4 AGCAGCGTC CACTG TGGTAAGCA X 4 0 4 AGCAGCGTC TGCATG GTGTGTTGC X 4 0 4 AGCAGCGTC TAATAC AATTGAGTT X 4 0 4 AGCAGCGTC AACTGT GTGAGTTGA X 4 0 4 AGCAGCGTC AAGTCT GTGTGCTGC X 4 0 4 AGCAGCGTC TACAGT GACTGCCGT X 4 0 4 AGCAGCGTC TGTGC CATGGAGCA X 4 0 4 AGCAGCGTC TCCTT GAGCGGTGC X 4 0 4 AGCAGCGTC TCCTTG GGCAGAGGT X 4 0 4 AGCAGCGTC ACGTG CCGCTAGGA X 4 1 3 AGCCGCGTC GCGGA GAGGGCGGC X 4 1 3 AGCAGTGTC CTGAGG GTGTGAAGG X 4 1 3 AGCAGTGTC AGATT AAGTGAGCC X 4 1 3 AGCATCGTC AATTA CAGTGAAAA X 4 1 3 AGCAGCGGC TGTGG CAGTGTGGT X 4 1 3 AGCAACGTC GTGACA GAGCCTGGA X 4 1 3 AGCAGTGTC ACAGT GTGTGAGAG X 4 1 3 AGCAGCGGC TCCCAG GAGAGGGGC X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGTAGCGTC TCGCT GTGTGAGTG X 4 1 3 AGCAACGTC AGCAGA GTCTCAGGA X 4 1 3 AGCAGCGTT ATTCT GAGTGATAT X 4 1 3 AGCAGTGTC CAGTA GTGTAAGGT X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 GGCAGCGTC GGGATA TGGTGAGGG X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGAGTC GCTCA CTGTGAGGC X 4 1 3 AGCAGCGGC AGCGGC GAGGGCGGC X 4 1 3 AGCAGTGTC AGAGCA GAGAGAGCC X 4 1 3 AGCATCGTC TGATCC TTGTGAGGG X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGGGTC TCCTG TAGTGAGTC X 4 1 3 ACCAGCGTC TGCTTC TGGTGAGGC X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGCATC AGCTG GAGGAAGGG X 4 1 3 AGCAGCGGC AACGAT GAGCAAGAA X 4 1 3 AGCAGTGTC AGCAGC AAGTGTGGT X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGCGGC CACAGA GGTTGAGGC X 4 1 3 AGCAGCGGC ACCTG GGGAGAGGC X 4 1 3 AGCAGTGTC AGTGGT GGAGGAGGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGAGTC CTGGGA GACTGAACA X 4 1 3 AGCAGTGTC AGATA GAGGGAGCC X 4 1 3 AGCAGTGTC CATTTG AAGGGAGGT X 4 1 3 TGCAGCGTC TGTGT GAGTGTCGT X 4 1 3 GGCAGCGTC TGTCT GTGTGAGCT X 4 1 3 AGCAGCGTG TTTTAA GAGTGAAAG X 4 1 3 AGCAGCGGC TGTGAA AGGTGAGGT X 4 1 3 AGCAGTGTC CAGGA GGAGGAGGA X 4 1 3 AGCAGTGTC TTGCAT GTGGGAGGT X 4 1 3 ACCAGCGTC TGCTTC TGGTGAGGC X 4 1 3 AGCAACGTC CATCCT GAGAGATGG X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC ACAGGT GAGTTGAGA X 4 1 3 AGCAACGTC CAGAA AATTGAGCA X 4 1 3 AGCAGTGTC TTTTT GAGTAGGCA X 4 1 3 AGCAGCGGC AGCAT TAGGGAGGT X 4 1 3 AGCAGTGTC CTCATG GGAGGAGGA X 4 1 3 AGCAGCGGC CAAGA GAGTGAATT X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGAGTC AGGGA GACTGAGTC X 4 1 3 AGCAGTGTC CAGCGT GAGGGAGAT X 4 1 3 AGCACCGTC TGGGA GTATGAGGC X 4 1 3 ACCAGCGTC CACTTC TGGTGAGGC X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AGAAAA GTCTCAGGA X 4 1 3 AGCAGGGTC CAAAA GAGTGATTT X 4 1 3 AGCAGTGTC AGCCCA GAGTGAATT X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGTGTC AACTAG GAGTAGGCA X 4 1 3 AGCAGCGGC ATTAC GAGTAAGCT X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AACAAA GTCTCAGGA X 4 1 3 AGCAGCTTC CTCTG GGGAGTGGA X 4 1 3 AGCAGTGTC TCCCC GAGGGAAAA X 4 1 3 AGCATCGTC CGGGG AGGTGAGAA X 4 1 3 AGCAGCGGC TCTCA AAGTGTGGT X 4 1 3 AGCATCGTC CGGGG AGGTGAGAA X 4 1 3 AGCAGCGTT CACACT CAGAGAGGT X 4 1 3 AGCAGCGGC CGGAGC AAGAGAGGG X 4 1 3 AACAGCGTC AATGT GTGTGAGAG X 4 1 3 AGCATCGTC CGGGG AGGTGAGAA X 4 1 3 AGCATCGTC CGGGG AGGTGAGAA X 4 1 3 AGCATCGTC TGGGG AGGTGAGAA X 4 1 3 AGCATCGTC CGGGG AGGTGAGAA X 4 1 3 AGCAGCATC AGCGA GAGGAAGGG X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCACCGTC CAGTGT GGGTGAAGC X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AACAGCGTC AACGT GAGTGAATT X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCACCGTC TCCTGA GGGTGAGTG X 4 1 3 AGCACCGTC CTTTCC GTGTGGGGT X 4 1 3 AGCAGGGTC AAAAAG TAGTGTTGA X 4 1 3 AGCAACGTC CCTCAT GAATAAAGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGCTTC TCTGA GGGAGTGGA X 4 1 3 GGCAGCGTC TGGGAT GAGGAAGGC X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGCGGC AACTT AAGAGTGGA X 4 1 3 AGCAGCGGC CTCAG AAGTGAGCC X 4 1 3 AGCAGTGTC TGCACA GAGTAGGCA X 4 1 3 AGCAGTGTC CCGAGG CTGTGAGGC X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGTGTC CAGCA CAGTGAGAT X 4 1 3 AGCAACGTC CAGAGG GAGGAAAGA X 4 1 3 AGCAGCGTG TTAATT AAGTGAGTC X 4 1 3 AGCAGGGTC TAAGG GAGTGATTT X 4 1 3 AGCACCGTC TGGGA GTTTCAGGA X 4 1 3 AGCACCGTC TGGGA GTTTCAGGA X 4 1 3 ATCAGCGTC CAGCGT GAGGTAGGC X 4 1 3 AGCATCGTC AATTA TAGTGAGAC X 4 1 3 AGCAACGTC AGCAAA GTCTCAGGA X 4 1 3 AGCAGCGAC ATCCT GAGTGGGCT X 4 1 3 AGCACCGTC CAGACA GAGCAGGGA X 4 1 3 AGCAGTGTC ATTTTC TGGTGAGGG X 4 1 3 AGCAGTGTC CTGTG GAGTGTTGG X 4 1 3 AGCAGCGGC GAGGT TAGTGTGGT X 4 1 3 AGCAGGGTC CACAGT GTGTGAGAT X 4 2 2 AGCACCGGC CGGCC GAGGGAGGG X 4 2 2 AGCAGAGTG CCAGG GAGTGAGAT X 4 2 2 AGCAAGGTC TGCATT GAGAGAGGC X 4 2 2 AGCATGGTC CAGCA GAGTGAGCC X 4 2 2 ATCAGTGTC ATCCTG GAGTAAGGT X 4 2 2 AGCATGGTC GTGGA AAGTGAGTA X 4 2 2 AGCAATGTC TGTGG GAGGGAGGC X 4 2 2 AGCATTGTC TGCAGT GAGTGTGGG X 4 2 2 AGCATTGTC TCCCTC CAGTGAGGG X 4 2 2 AGCAAGGTC AGTGTC TAGTGAGGG X 4 2 2 AGCAGGGTA GTGGT GAGTAAGGT X 4 2 2 AGCAGCGCA GGCCG GGGTGAGGG X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCATGGTC AGGTTC CAGTGAGGG X 4 2 2 AGCTGCATC ACCTT GAGTGAGTC X 4 2 2 AGAAACGTC CAGGTA GAGTGAAAA X 4 2 2 TGCAGTGTC CCATG GAGGGAGGT X 4 2 2 AACAACGTC CAGCAG GAGTGTGAA X 4 2 2 AGCAAGGTC TTAAA GAGCGAGTA X 4 2 2 AGCAGTGTG GGGCA GTGTGAGGC X 4 2 2 AGTAGTGTC CTGTG GAGGGAGGC X 4 2 2 AGCAGGGTT GGTTTC TAGTGAGGC X 4 2 2 AGCATGGTC AGGTTC CAGTGAGGG X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCACCGTA TTCTGC TAGTGAGGG X 4 2 2 AGCTGTGTC TGGTGT GAGTGAGAG X 4 2 2 AGCCGGGTC CCCAC GAGTGAGTG X 4 2 2 AACAGGGTC AGAGAA GAGTGAGAC X 4 2 2 AGCACTGTC TTGGA AAGTGAGGG X 4 2 2 AGCAACGTG GCAGAG GAGGGAGGT X 4 2 2 AGCAGGGTG GGAACT GAGGGAGGT X 4 2 2 AGCACAGTC TTGGG GAGAGAGGC X 4 2 2 AGCATTGTC ACACA GAGTGAATA X 4 2 2 ATCAGAGTC AGCTTA GAGTGAGAG X 4 2 2 AGCAACCTC CAGGT GAGGGAGGC X 4 2 2 AGCGGAGTC GCTGGG GAGAGAGGG X 4 2 2 AGCATGGTC CATTTC TAGTGAGGC X 4 2 2 TGCAGTGTC CACAGC AAGTGAGGT X 4 2 2 GGCACCGTC CTCCTG GAGGGAGGC X 4 2 2 AGCAAAGTC TCTAAA GAGTGTGGT X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCAGCATT GCACGG GGGTGAGGT X 4 2 2 AGCAGTGAC AGCGG GAGTGAGCC X 4 2 2 AGCAGTGAC CAATCT GAGTGAGCC X 4 2 2 AGCAATGTC AACAGA GGGTGAGGG X 4 2 2 AGCAACATC TACTAA GAGTGAGCC X 4 2 2 TGCAGGGTC AGGGT GTGTGAGGC X 4 2 2 AGCAACGGC GACTG GAGTGACCA X 4 2 2 AGCATGGTC CAGTTC CAGTGAGGG X 4 2 2 GGCAGTGTC CTCCCA CAGTGAGGC X 4 2 2 AGCACCGGC CCTGGG CAGTGAGGG X 4 2 2 AACAGTGTC TATAAA TAGTGAGGG X 4 2 2 AGCAAAGTC AGAGG GAGTGATGT X 4 2 2 AGCAATGTC TGCAT GAGGGAGGT X 4 2 2 AGCAGTCTC CAGGC GAGAGAGGG X 4 2 2 AGCAAAGTC CTTGGT AAGTGAGGG X 4 2 2 AGCAGCAGC TTAGA GAGTGAGCC X 4 2 2 AACATCGTC AGTGG GAGTGTGAA X 4 2 2 AGCAACATC CTTGGG GAGTGAAGT X 4 2 2 AGCCCCGTC AAGCA GAGGGAGGC X 4 2 2 AGCAGCGGT TCTCA GAGTGTGGC X 4 2 2 AGCAAGGTC TGAGAA GAGTGGTGA X 4 2 2 AACAGAGTC AGAGAG GTGTGAGGC X 4 2 2 GGCAGCGTG TGACAG AAGTGAGGG X 4 2 2 AGCATAGTC TCCCA GAGTGAGTG X 4 2 2 AGCCGTGTC CCCTT AAGTGAGGG X 4 2 2 AGCATGGTC AGGTT CAGTGAGGG X 4 2 2 AGTAGTGTC TGGTG GAGTGAGTT X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCAGCATT TCAAGA GAGTGAGAG X 4 2 2 CGCAGTGTC TGGTCA CAGTGAGGC X 4 2 2 AGCAGGGTG GGGAA GAGGGAGGT X 4 2 2 AGCAGGGTA ATGTGA GAGTGAGTG X 4 2 2 AGCATAGTC ACTTA GAGTGTGGG X 4 2 2 AGCATGGTC AGGTTC CAGTGAGGG X 4 2 2 TCCAGCGTC GTGACA GAGTGAGAC X 4 2 2 AGCACTGTC CTGTCA GAGTGTGGC X 4 2 2 AGCATAGTC CAGTT CAGTGAGGC X 4 2 2 AGCAGTGTG CACCAC GAGAGAGGC X 4 2 2 AGCAACGGC AGGAGA GAGAGGGGA X 4 2 2 AGCCGGGTC ACCGA GAGTGAGTG X 4 2 2 AGCAATGTC AATTTT CAGTGAGCA X 4 2 2 AGCAACGTG TGGAG CAGTGAGGG X 4 2 2 AGCACGGTC AGTCTT CAGTGAGGG X 4 2 2 AGCATGGTC ATGTTA TAGTGAGTA X 4 2 2 AGCAGGGTA GGGAG GAGTGAGTG X 4 2 2 AGCGGTGTC TGAAAA AAGTGAGGG X 4 2 2 AGCAAGGTC CATCCA GAGAGAGGC X 4 2 2 AGCACCTTC TAGGGA GTGTGAGGC X 4 2 2 AGCAAAGTC TCACAG GAGGGAGGC X 4 2 2 AGCAAGGTC TGGGA GAGTGATGT X 4 2 2 AGCAGCAGC TGCCGG GAGCGAGGC X 4 2 2 AGCAACGGC CTGGG GAGTGTGGG X 4 2 2 TGCAGCGAC TGAAGT GAGTGAGTG X 4 2 2 GGCAGCTTC CCAGT GAGTAAGGT X 4 2 2 AACAGTGTC AGTGAT TAGTGAGGG X 4 2 2 AGCTTCGTC CAGAG CAGTGAGGG X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCAACGTG ATGAAA GAGTGAGAT X 4 2 2 AGCAATGTC AGTCTC AAGTGTGGA X 4 2 2 TGCAGTGTC CCTGG GAGGGAGGT X 4 2 2 AGCAACGGC CAGTCC CAGGGAGGA X 4 2 2 AGCATCGGC TCCTC AAGTGAGGC X 4 2 2 AGCATCGGC TCCTC AAGTGAGGC X 4 2 2 AGCATCGGC TCCTC AAGTGAGGC X 4 2 2 AGCAAGGTC AGAGA GTGTGAGGC X 4 2 2 AGCGGAGTC CAGAG AAGTGAGGG X 4 2 2 AGCACCATC AGCAC CAGTGAGGT X 4 2 2 AGCTGCTTC CCCTA GAGTGAGAG X 4 2 2 AGCAACATC ACTTT GAGTAAGGC X 4 2 2 AACAGTGTC AAATC AAGTGAGGT X 4 2 2 AGCATCGTA CCTCAA GAGACAGGA X 4 2 2 AGCATGGTC GGTTTC CAGTGAGGG X 4 2 2 AACAGCTTC CCAGCT TAGTGAGGC X 4 2 2 AGCAACTTC CCTGGA GGGTGAGGG X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCAGGGTG GGGTGT GAGGGAGGC X 4 2 2 AGCATTGTC TGAAG GAGAGGGGA X 4 2 2 GGCAGCGTG TGTGA GAGTGAGCT X 4 2 2 AGCTGTGTC CCCCA GAGTGAGAG X 4 2 2 AGCAGCATT CATGT GAGTGAGAT X 4 2 2 AGCAGTGTT TCTTC GAGTGTGGC X 4 2 2 AGCACAGTC ACCGA TAGTGAGGC X 4 2 2 GGCAGCTTC AGGGC AAATGAGGA X 4 2 2 AGCATTGTC ATAATA GAGAGAGGT X 4 2 2 AGCATGGTC ATGGA AAGTGAGTA X 4 2 2 AGCAGGGTG GTAAA GAGGGAGGT X 4 2 2 AGCAACTTC TCCAC TAGTGAGGG X 4 2 2 AGCAGCAGC CGGTG GTGTGAGGC X 4 2 2 TGCAGGGTC TCTTA GAGTGAGTT X 4 2 2 TGCAGCGTT GGGCT CAGTGAGGG X 4 2 2 AGCAGCATA TAATA GAGTGAGTC X 4 2 2 AGCAGTGTG CTAAG GAGAGAGGC X 4 2 2 AACAGCATC TCAGCT GGGTGAGGC X 4 2 2 AGCAGTGTG CCTTGG GTGTGAGGG X 4 2 2 AACAGAGTC GTTCA GTGTGAGGC X 4 2 2 AGCAACGTT AGCAG GAGTGTGGT X 4 2 2 AGCAAAGTC TGTAAA GAGTGTGTA X 4 2 2 TGCATCGTC CTATG GAGGGAGGT X 4 2 2 AGCAAGGTC TTGTTG GAGGGAGGG X 4 2 2 GGCACCGTC ATCCT GAGTGGGGC X 4 2 2 AGCAGAGTA AGGGAG GAGTGAGAG X 4 2 2 AGCAAAGTC ACAGG GAGTGAGCG X 4 2 2 AGAAGTGTC ACTGTC CAGTGAGGC X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCAAAGTC AGCCA GAGGGAGAA X 4 2 2 AGCAAAGTC TGGAGT GAGTGTGTA X 4 2 2 GGCAGTGTC CGGCT GAGGGAGGG X 4 2 2 AGCAGCAAC AGTGT GAGTGAGTT X 4 2 2 AGCATTGTC TAGCA GGGTGAGAA X 4 2 2 AGCAAGGTC ACTGAG GAGGGAGGC X 4 2 2 AGCATCGGC AGCTTG GAGAGAGGT X 4 2 2 AGCAGGGTG GTAGGG GAGGGAGGT X 4 2 2 AGCAGCGCT TCTCA AAGTGAGGC X 4 2 2 AGCAGGGTG GTGTGA GAGTGAGTG X 4 2 2 TGCAGCGTG GCCACA GAGTGAGAC X 4 2 2 TGCAGTGTC ATTTGA GAGTAAGGT X 4 2 2 AGCAGGGTG AGCACT AAGTGAGGC X 4 2 2 AACAGGGTC AGTGGG GAGAGAGGC X 4 2 2 AACAGCGGC CTATT GTGTGAGGG X 4 2 2 AGCAACGTT CAGCT CAGTGAGGT X 4 2 2 AGCAGTGTT GCCCCA GGGTGAGGT X 4 2 2 AGCACCGTG TGGGGA GAGGGAGGT X 4 2 2 AGCAACGTT CTGTG GAATGAGCA X 4 2 2 AGCCACGTC GAATG GATTGAGGG X 4 2 2 AGCAGGGTG GAGCGC GAGGGAGGC X 4 2 2 TGCAGCGGC CTCAG AAGTGAGGG X 4 2 2 AGCATTGTC TCCCTT GAGTATGGA X 4 2 2 GGCACCGTC CTTTG CAGTGAGGT X 4 2 2 AGCATGGTC GGGCAC TAGTGAGGC X 4 2 2 AGCACCATC ATGAAT GTGTGAGGC X 4 2 2 AGTAGTGTC TAATAG GTGTGAGGT X 4 2 2 AGCACCATC AAGATA GTGTGAGGC X 4 2 2 AGCCACGTC ACCTG AGGTGAGGA X 4 2 2 AGCAACATC TGTGTA GAGCGAGGT X 4 2 2 AGCCGAGTC CTTGT GGGTGAGGC X 4 2 2 ACCAGTGTC CTGCAG TAGTGAGGC X 4 2 2 AGCAACGAC GGGCT GCGTGTGGA X 4 2 2 AGCAGCATT GACCT GAGTGAGAT X 4 2 2 AGCAGCATT GACCT GAGTGAGAT X 4 2 2 CGCAGTGTC TTCCC CAGTGAGGC X 4 2 2 TGCATCGTC AGAGA GTGTGAGGG X 4 2 2 AGCTGAGTC CCCGGC AAGTGAGGC X 4 2 2 AGCAACGTG TGCCA GTGTGAGGG X 4 2 2 AGCAGTGGC TGGGCA TAGTGAGGC X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCACCATC TAGGCA GAGGGAGGC X 4 2 2 AGCACAGTC ATGGTG GAGTAAGGG X 4 2 2 AGCATGGTC AGGTTC CAGTGAGGG X 4 2 2 AGCATGGTC AGGTTC CAGTGAGGG X 4 2 2 AGTAACGTC ATTTCA GAGTGCAGA X 4 2 2 AGCAACTTC TAGGAT GAGTGTGAA X 4 2 2 AGCAGCATT GACAT GAGTGAGAT X 4 2 2 AGCAATGTC TGCTGT GGGTGAGGG X 4 2 2 AGCAATGTC TGCCAT GAGTGTGAA X 4 2 2 AGCAGATTC GGAATT GAGTGAGTG X 4 2 2 CACAGCGTC GGAGG GAGGGAGGG X 4 2 2 AGCAGCGAT CTAAT GAGGGAGAA X 4 2 2 AGCACCGTG AGACTT GAGTGAGCC X 4 2 2 ATCAGTGTC CTGGG GAGTGTGGT X 4 2 2 AGCAACCTC ACGGG GAGGGAGGC X 4 2 2 AGCAACTTC AGAAGT GAGTTAGGG X 4 2 2 AGCAACTTC CACTA GAGAGAGGC X 4 2 2 AGCAACGTG GCAGAT GAGAGAGGT X 4 2 2 AACAGCATC AAATGC GGGTGAGGC X 4 2 2 ACAAGCGTC TGTAA GAGTGAGTC X 4 2 2 TCCAGCGTC ACCTA AAGTGAGGG X 4 2 2 AGCAAGGTC AGGAA GAGAGAGGC X 4 2 2 AGTAGCGTT TTGTC CAGTGAGGT X 4 2 2 AGCAGTGTT TGCTAA CAGTGAGGC X 4 2 2 AGCATGGTC AGGTTC CAGTGAGGG X 4 2 2 AGCAGCGGA GGTCA GAGTGAGTT X 4 2 2 AGCACCGAC TCCAT CAGTGAGGT X 4 2 2 AGCAGTGAC ATGAG GAGTGAGCC X 4 2 2 AGCAGGGTT TCTGCA GTGTGAGGT X 4 2 2 AGCAGCATG GTTAG GAGTGAGAT X 4 2 2 ATCAGAGTC AAAGG GAGGGAGGC X 4 2 2 AGCAGGGTT GGAAGA AAGTGAGGG X 4 2 2 AGCAGGGTG GGCAA GAGGGAGGC X 4 2 2 GGCAGTGTC TCAAAC GAGGGAGGG X 4 2 2 GGCATCGTC ACTCTT GAGTGAGAG X 4 2 2 AGCACCGTG ACTTC GAGGGAGGT X 4 2 2 AGCAGAGTT TAAAA TAGTGAGGG X 4 3 1 GACAGCCTC ATTAT GAGTGAGGC X 4 3 1 AGGGGGGTC TTGGGA GAGTGAGGT X 4 3 1 AGCCTGGTC CGTGA GTGTGAGGA X 4 3 1 GGCAGCGAT GAGATT GAGTGAGGG X 4 3 1 AACAAGGTC ATAAA GAGGGAGGA X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 GGCAGAGTG GAGGAA GAGTGAGGC X 4 3 1 AGCTGGGTT GGAGTG GAGTGAGGG X 4 3 1 AGCAAAGGC TAAAGA GTGTGAGGA X 4 3 1 AGTAACGGC GGGGCT GAGGGAGGA X 4 3 1 AGCATTGTT CTCAG AAGTGAGGA X 4 3 1 CACAGCATC AGCAG GAGTGAGGG X 4 3 1 AGCCACATC AGTCT GAGTAAGGA X 4 3 1 AGCAGCACA CAGGCC GAGTGAGGT X 4 3 1 AGCATTGCC TTTTG GAGTGAGGG X 4 3 1 AGAAGTGCC ATCTGG GAGTGAGGG X 4 3 1 ATCAGCATA CAGGG GAGTGAGGC X 4 3 1 AGCAGGTAC GTGCCT GAGTGAGGC X 4 3 1 AACTACGTC CACCA GAGTGGGGA X 4 3 1 AGAAGTGCC ATCTAG GAGTGAGGG X 4 3 1 AGGAGTCTC ATACT GAGTGAGGT X 4 3 1 TCCAGCGGC CACAG GAGTGAGGT X 4 3 1 AGCTCAGTC TCCCA GGGTGAGGA X 4 3 1 AGCTCAGTC TCTCA GGGTGAGGA X 4 3 1 AACAGTATC TATTCT GAGTGAGGC X 4 3 1 GGAAGTGTC TTACTG GAGTGAGGT X 4 3 1 CTCAGAGTC AAACA GAGTGAGGT X 4 3 1 AACAGTGTT TTGGCC GAGTGAGGG X 4 3 1 CTCAGCTTC CTGTG GAGTGAGGC X 4 3 1 AGCAGCTGT AGGGA GAGTGAGGT X 4 3 1 AGCTGTGTG ATCCT GAGTGAGGG X 4 3 1 AGGTGTGTC TTTGGA GAGTGAGGC X 4 3 1 ATTAGAGTC TGGGTT GGGTGAGGA X 4 3 1 AGCCGGCTC GCGAGT GAGTGAGGG X 4 3 1 AGCACCAGC CCGGGT GAGTGAGGT X 4 3 1 TTCAGCGTT GTGAA GAGTGAGGC X 4 3 1 AGCTCCTTC GAGGA GAGTGAGGC X 4 3 1 AAGAGTGTC CTGGTT GAGTGAGGC X 4 3 1 TGCAGGGTA GTTGG GAGTGAGGT X 4 3 1 AGGATCATC CAGAGT GAGTGAGGC X 4 3 1 GTCTGCGTC CGAAGG GAGTGAGGG X 4 3 1 ATGAGCGAC TGATG GAGTGAGGG X 4 3 1 CCCAGGGTC CACAGA GAGTGAGGC X 4 3 1 AGTACAGTC CATTTG GAGGGAGGA X 4 3 1 AGCTTCCTC CATCTT GAGTGAGGC X 4 3 1 AGAAGTGCC TCCTG GAGTGAGGG X 4 3 1 GGCAGAGTG GATCA GAGTGAGGC X 4 3 1 AGCAGTTCC TAAAA GAGTGAGGG X 4 3 1 GGCACTGTC GCTCA GAGTGAGGT X 4 3 1 AGCAGGCAC AGCCTG GAGTGAGGC X 4 3 1 AGTGGAGTC CCCTA GAGTGAGAA X 4 3 1 AGGACAGTC GCAGA GAGTGAGGC X 4 3 1 AGCTGTGTG CTGCCA GAGTGAGGC X 4 3 1 AGCAAGGTG GGTGGC GTGTGAGGA X 4 3 1 TGCTGTGTC CCCAGT GAGTGAGGG X 4 3 1 GGCACAGTC TGACA GAGAGAGGA X 4 3 1 AGCTCAGTC TCACA GGGTGAGGA X 4 3 1 GTCAGTGTC ATGCTT GAGTGAGGC X 4 3 1 GGAAGGGTC CCAGTG GAGTGAGGT X 4 3 1 AGGAGCAAC AAAGA GAGTGAGGG X 4 3 1 AGCGGTTTC AGTGA GAGTGAGGC X 4 3 1 AGCAGCACG GGGTG AAGTGAGGA X 4 3 1 AGAAGGGTG GAGAAG GAGTGAGGT X 4 3 1 TGCTGTGTC CATCCA GAGTGAGGG X 4 3 1 AGCTCAGTC AACTG GGGTGAGGA X 4 3 1 AGCAAGGTT AGGTTC TAGTGAGGA X 4 3 1 AGCTCAGTC TCTCA GGGTGAGGA X 4 3 1 AGCACGGTG GTCAA GAGTGAGGC X 4 3 1 AGCAGGGAT TTGCA GAGTGAGGC X 4 3 1 ATCAGCTTT GGGGTT GAGTGAGGT X 4 3 1 AGCACAGAC AGCAT GAGTGAGGC X 4 3 1 CCCAGCTTC TCAGG GAGTGAGGC X 4 3 1 CGCCCCGTC TGGGA AAGTGAGGA X 4 3 1 AGCAGAGGT TCCCA GAGTGAGGC X 4 3 1 AGCCACCTC CCCTGC GAGTAAGGA X 4 3 1 AGCCCTGTC TGTTAA GAGTGAGGT X 4 3 1 AGCAGCAGT CTCTG GAGTGAGGT X 4 3 1 AGCCACTTC TAGGGA GAGTGAGTA X 4 3 1 AGGTGCGGC AGGTA GAGTGAGGG X 4 3 1 AGCTGTGTG GTTGG GAGTGAGGG X 4 3 1 AGGCGCTTC ATTTAT GAGTGAGGT X 4 3 1 AGGAGTCTC ACGATA GAGTGAGGT X 4 3 1 ATCATCCTC CGCACT GAGTGAGGG X 4 3 1 AGCCGGGTA GGGGAT GAGTGAGGC X 4 3 1 AGCAACTGC TTTGTG GAGTGAGGT X 4 3 1 GGCAGCATT TGAAGG GAGTGAGGG X 4 3 1 CACAGCATC TGAGGT GAGTGAGGG X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 ACCCGTGTC ACAGTT GAGTGAGGG X 4 3 1 AGCCCTGTC TGCTGG GAGTGAGGG X 4 3 1 GGACGCGTC AGGCT GAGTGAGGT X 4 3 1 AGGAACCTC GTGCG GAGTGAGGC X 4 3 1 AGCTGTGTG GCCTT GAGTGAGGC X 4 3 1 CGCTGCGAC CTTCA GAGTGAGGC X 4 3 1 GGTAGAGTC AGACA GAGTGAGGG X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 ACCAACCTC CTGTCA GAGTGAGGC X 4 3 1 AGCAGTCTG CTGCAG GAGTGAGGG X 4 3 1 TGCTGTGTC CTCACA TAGTGAGGA X 4 3 1 AGAAACTTC AAGAAG GAGTGAGGT X 4 3 1 AACAATGTC GTCACA GAGTGAGTA X 4 3 1 AGAAGGGTG AATAAG GAGTGAGGT X 4 3 1 TGCAGCGGA GGCAG GAGTGAGGG X 4 3 1 AGCTGTGTG ACCTC GAGTGAGGC X 4 3 1 AATAGAGTC CTGGG GAGTGAGGC X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 AGTAGCATT TTTAGT GAGTGAGGG X 4 3 1 ACCGGAGTC ATCCCT GAGTGAGGG X 4 3 1 AGCAGTCTG AAGGG GAGTGAGGG X 4 3 1 AGCAGCACA CAGGCC GAGTGAGGT X 4 3 1 AGCAGCCAT CAGAG GAGTGAGGC X 4 3 1 GCCAGGGTC CAAATG GAGTGAGGC X 4 3 1 AGCATCTTA GTGAT GAGTGAGGT X 4 3 1 AGGAGCAAC AGAGA GAGTGAGGG X 4 3 1 AGCAGGTTT ATTAGG GAGTGAGGG X 4 3 1 GACAGCCTC TCCCA GAGTGAGGC X 4 3 1 AGCAGCAAT GGCAG GAGTGAGGT X 4 3 1 GGCAGCGGT AGAGA TAGTGAGGA X 4 3 1 AGTGGAGTC CTGGA GAGTGAGTA X 4 3 1 AGCCTGGTC TGGCC GTGTGAGGA X 4 3 1 AGAACCGAC CAGCCA GAGTGAGGG X 4 3 1 AGCAACATG ACCCA GAGTGAGGG X 4 3 1 AGCTCAGTC TTGCA GGGTGAGGA X 4 3 1 AGCTCAGTC TCACA GGGTGAGGA X 4 3 1 TGCAATGTC AAGCTT GAGTGAGAA X 4 3 1 GGCCCCGTC ACGGT GAGTGAGGG X 4 3 1 AGCTCAGTC TCACA GGGTGAGGA X 4 3 1 AGCAATGTA GGGAGG GAGTGAGGG X 4 3 1 AGTAACATC CTGTTT GTGTGAGGA X 4 3 1 ATCATTGTC TCCACT GAGTGAGAA X 4 3 1 AGTAGAGTT TAGGG GAGTGAGGG X 4 3 1 AGCAGGGGT CAGCTG GAGTGAGGG X 4 3 1 TGCTGTGTC TTCCTG GAGTGAGGC X 4 3 1 ATTAGAGTC AGAGCA GGGTGAGGA X 4 3 1 AGAAGGGTG AGCAA GAGTGAGGT X 4 3 1 CTCAGTGTC TCTGTG AAGTGAGGA X 4 3 1 AGCTGTGTT CTGGAT GAGTGAGGT X 4 3 1 AGTACAGTC TAGCCA GAGGGAGGA X 4 3 1 AGCCGCTTT ATTCAA GAGTGAGGG X 4 3 1 ACCGGTGTC GTCGT GAGTGAGGG X 4 3 1 AGCAGTGCT GAGGC GAGTGAGGC X 4 3 1 AGCTCAGTC TCACA GGGTGAGGA X 4 3 1 ATCTGCATC TCTCTT GAGTGAGGT X 4 3 1 AGCACAATC CCCCAA GAGTGAGGG X 4 3 1 AGCTCAGTC TCACA GGGTGAGGA X 4 3 1 ATCATCATC TTGGA GAGTGAGGC X 4 3 1 GGTAGAGTC ACTGTA GAGTGAGGG X 4 3 1 AGCTGTGTG CTGGGG GAGTGAGGC X 4 3 1 ATGAGTGTC AGGTG GAGTGAGGG X 4 3 1 GGCAGAGTG GTCCAG GAGTGAGGC X 4 3 1 AGGAGTCTC CAGGGG GAGTGAGGC X 4 3 1 AGCCAAGTC CTGAG GGGTGAGGA X 4 3 1 CGCTGAGTC CAGAG GAGTGAGGC X 4 3 1 GGCTCCGTC TTATGT GAGTGAGGC X 4 3 1 AGCAGCAGT GAGGA GAGTGAGGC X 4 3 1 AGTACTGTC AACTA CAGTGAGGA X 4 3 1 ATGAGCGGC CGGTAG GAGTGAGGT X 4 3 1 TGCAAGGTC AGGAT AAGTGAGGA X 4 3 1 AGTACAGTC ACTGT TAGTGAGGA X 4 3 1 ATCATTGTC AGGTT GAGTGAGAA X 4 3 1 CTCAGCGGC TGCTGT GAGTGAGGG X 4 3 1 AGCAGTCCC ATCCAA GAGTGAGGG X 4 3 1 AGCACAGGC TGGACA GAGTGAGGT X 4 3 1 AGCAACCAC CTCCTG GAGGGAGGA X 4 3 1 AGTAAGGTC AAGGA GAGGGAGGA X 4 3 1 CGCCCCGTC TGGAG AAGTGAGGA X 4 3 1 TGCACAGTC ACATG GTGTGAGGA X 4 3 1 AGCAGCAAG TGGCA GAGTGAGGC X 4 3 1 AGCTCAGTC TCACA GGGTGAGGA X 4 3 1 GGCAGGGTT TCTCA GAGTGAGGT X 4 3 1 AGGATGGTC CTTCC AAGTGAGGA X 4 3 1 AGCAACCCC ATTTT GAGTGAGGG X 4 3 1 AGAAGCCAC ATCAGT GAGTGAGGG X 4 3 1 ACCAATGTC ACCTGT GTGTGAGGA X 4 3 1 AGGTGCGTG GAGTG GAGTGAGGG X 4 3 1 AGCAGTGAA GGGAA GAGTGAGGC X 4 3 1 AGCTGAGTG ACAGCT GAGTGAGGG X 4 3 1 AGCAGTGCG TGCAT GAGTGAGGG X 4 3 1 GGCGGGGTC TGCTC GAGTGAGGC X 4 3 1 AGAATAGTC TTAGA CAGTGAGGA X 4 3 1 AGCAGGGAT TTGCA GAGTGAGGC X 4 3 1 GGAAGTGTC CAAGG GAGTGAGGT X 4 3 1 ATCAATGTC CTCTGT GAGTGAGGG X 4 3 1 CCCAGCTTC CTGGG GAGTGAGGC X 4 3 1 AGGTGCGGC AGGTA GAGTGAGGG X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 AGCAACATG GCTCA GAGTGAGGG X 4 3 1 TGCGCCGTC TACTAG GAGTGAGGC X 4 3 1 AGCAAAGTT TAACAA GAGTGAGAA X 4 3 1 AGCAAAGTT TAACAA GAGTGAGAA X 4 3 1 AGCAAAGTT TAACAA GAGTGAGAA X 4 3 1 AGCAAAGTT TAACAA GAGTGAGAA X 4 3 1 AGCAAAGTT TAACAA GAGTGAGAA X 4 3 1 AGTATCATC CGGCT GAGTGAGGT X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 AGGAGCAAC CACAGG GAGTGAGGG X 4 3 1 AGCAGCTCG CTGAG GAGTGAGGG X 4 3 1 AGCTGAGAC TTAGA GAGTGAGGT X 4 3 1 AGCAATGTG AGTTGT GAGTGAGGG X 4 3 1 AGAAGCGGT GCGTCT GAGTGAGGT X 4 3 1 AGAAGTGCC ATCTGT GAGTGAGGG X 4 4 0 GGATGAGTC TGGAG GAGTGAGGA X 4 4 0 ACAGGTGTC CAAGAT GAGTGAGGA X 4 4 0 CTGGGCGTC CCTCCA GAGTGAGGA X 4 4 0 CCCGGGGTC TTCAGT GAGTGAGGA X 4 4 0 TGGCACGTC TGAGG GAGTGAGGA X 4 4 0 AGCTCAGTA CAAAAA GAGTGAGGA X 4 4 0 AAAAGGTTC AGAGG GAGTGAGGA X 4 4 0 GACATCATC AGAACT GAGTGAGGA X 4 4 0 AGCACTATT CTATTA GAGTGAGGA X 4 4 0 CCCTGAGTC TGAGG GAGTGAGGA X 4 4 0 TGGGGAGTC AGTGC GAGTGAGGA X 4 4 0 AACAGGGCT TCTGA GAGTGAGGA X 4 4 0 AGCAAAGCT CGAGA GAGTGAGGA X 4 4 0 AACATTGTT TCAGT GAGTGAGGA X 4 4 0 AGACACTTC ATGAAT GAGTGAGGA X 4 4 0 GCCCACGTC TTCGTG GAGTGAGGA X 4 4 0 AACATGGTT GTGTGG GAGTGAGGA X 4 4 0 GGTACAGTC TTCGCC GAGTGAGGA X 4 4 0 GGCATGGTG AGAGTG GAGTGAGGA X 4 4 0 GGAAGTCTC AGGAT GAGTGAGGA X 4 4 0 ATCTTGGTC AGGGCA GAGTGAGGA X 4 4 0 ATCAGGTCC CAATT GAGTGAGGA X 4 4 0 GGCATGGTG TAAAGA GAGTGAGGA X 4 4 0 TGAAACGTT GCAGG GAGTGAGGA X 4 4 0 TGAATCGGC AACAA GAGTGAGGA X 4 4 0 ATACACGTC TCCTG GAGTGAGGA X 4 4 0 GGGAAGGTC CTTGG GAGTGAGGA X 4 4 0 CACTGTGTC GGGTGA GAGTGAGGA X 4 4 0 ATCTTTGTC TTCCT GAGTGAGGA X 4 4 0 CTGAGGGTC ATTGG GAGTGAGGA X 4 4 0 ATGTGAGTC TTCCTT GAGTGAGGA X 4 4 0 AAAGTCGTC AGCTAT GAGTGAGGA X 4 4 0 AACAATGTT CGCCT GAGTGAGGA X 4 4 0 GGGAAGGTC CTATGG GAGTGAGGA X 4 4 0 GGATGTGTC TTCAGG GAGTGAGGA X 4 4 0 TCCACAGTC TGGGT GAGTGAGGA X 4 4 0 AGCAAAGCT ATATGG GAGTGAGGA X 4 4 0 CCCTGGGTC CCAGGG GAGTGAGGA X 4 4 0 GTGAGGGTC TCTGGA GAGTGAGGA X 4 4 0 AGCCAGGTT GAAAAG GAGTGAGGA X 4 4 0 AGCATGGCT TATGG GAGTGAGGA X 4 4 0 AGCTCAGGC AGGGG GAGTGAGGA X 4 4 0 CCCTGGGTC TGCTG GAGTGAGGA X 4 4 0 AGCAACAGA TGAAG GAGTGAGGA X 4 4 0 AGCATGGCT GGAATG GAGTGAGGA X 4 4 0 AGCTAAGTT CTTGTA GAGTGAGGA X 4 4 0 AACTTTGTC CTGAA GAGTGAGGA X 4 4 0 AACATGGTT CCTTCT GAGTGAGGA X 4 4 0 CGCCACGGC TGGGAG GAGTGAGGA X 4 4 0 CTCATTGTC CAGGA GAGTGAGGA X 4 4 0 CCCTGGGTC ATGTGA GAGTGAGGA X 5 1 4 AGCAACGTC AAAGAT CACTGATCA X 5 1 4 AGCAGCGGC GACAGC AGAGGAGGA X 5 1 4 AGCAGCGGC AAGTGG GAGTAGGAT X 5 1 4 AGCAGCGGC GGCACC ACGTGCGCA X 5 1 4 AGCACCGTC AATCAG GTGCGAGTC X 5 1 4 AGCACCGTC AAGAGT CAGTGTTTA X 5 2 3 AGCACAGTC ACCTCT GAGTGACAC X 5 2 3 AGCAACGTA TCGAT GAGGGTAGA X 5 2 3 AGCATCGGC AGGCA GAGTAAGTC X 5 2 3 AACAACGTC CTGAAC GTGAGAGAA X 5 2 3 AGCATAGTC CGTGTA GTGAGAGAA X 5 2 3 AGCATGGTC TTAATG GAGTGATAG X 5 2 3 AGCTGTGTC TGCCTT GGGTGATGC X 5 2 3 AGCAATGTC ATGTC CAGTGAGCC X 5 2 3 AGCATTGTC CAAGGA GAGTAAGTG X 5 2 3 AGCAGCTGC TCTCAA GAGTATGGG X 5 2 3 TGCAGTGTC TGGAGT GTGTCAGGC X 5 2 3 AGCATTGTC CTCCTC TGGTGAGGT X 5 2 3 AGCATTGTC CCAAAA GTGAGGGGA X 5 2 3 AGCAATGTC TACCA CAGTGAGAC X 5 2 3 AGCAACGTT CTTTAT GTAAGAGGA X 5 2 3 AGCAACTTC ACTTAG GCGTGGGAA X 5 3 2 AGGCGAGTC TCTTTA GTGTGAGGC X 5 3 2 AGCCACGTT AGGGGT AAGTGAGGG X 5 3 2 AGTATCGTG ATTGA AAGTGAGGC X 5 3 2 AGCAAGGTA GCTTG GAGTGAGAC X 5 3 2 TGCAGCTGC AAAAG AAGTGAGGG X 5 3 2 AGTATCTTC TGGTGT GAGTGAGAT X 5 3 2 TGCAGTTTC TCAAAG GAGAGTGGA X 5 3 2 ATCAGGGGC CCACTA GAGTAAGGG X 5 3 2 AGTTGCTTC TGCATT GAGTAACGA X 5 3 2 AGCTACGTG CCCGGC CAGTGAGGG X 5 3 2 AGCTTAGTC TGAGT GTGTGAGGT X 5 3 2 ATCAGGGGC TGAAG GAGTAAGGG X 5 3 2 ATCAGGGGC TGAAG GAGTAAGGG X 5 3 2 AGCAACCCC TCTGCT GAGGGAGGC X 5 3 2 AGCATGGTA TGATGT AAGTGAGGG X 5 3 2 CATAGCGTC AGATTG GAGTAAGGT X 5 3 2 TGCAGCTGC TGTCAG AAGTGAGGG X 5 3 2 AGCTAGGTC CCCTG CAGTGAGGG X 5 3 2 AGCTTGGTC AGTGAA GAGAGAGGT X 5 3 2 AGCAACTAC ATATCT GTGTGAGGC X 5 3 2 AGCAACCCC TCTGCT GAGGGAGGC X 5 3 2 GTCAGTGTC CTGGAA AAGTGAGGG X 5 3 2 TGCAGTGTA GCTGGA GAGGGAGGT X 5 3 2 CTCATCGTC CAGGCT GAGTGAGTC X 5 3 2 AGTAACATC AAGTCA TAGTGAGGC X 5 3 2 AGCTATGTC CTAAAG AAGTGAGGG X 5 3 2 GTCCGCGTC TTGTTT GAGTAAGGG X 5 3 2 AGCCTTGTC ACTGA AAGTGAGGC X 5 3 2 AGCACAGCC ACATCT GTGTGAGGC X 5 3 2 AGCAACATT CTAAGC GAGTGAGTC X 5 4 1 AGTGTGGTC GGAGCA GAGTGAGGG X 5 4 1 ACTAATGTC ATGCTA GAGTGAGGT X 5 4 1 TACATTGTC TAGGAG GAGTGAGGG X 5 4 1 ATCAATGGC CAGAT GAGTGAGGG X 5 4 1 CGGGGAGTC CCAGGG GAGTGAGGG X 5 4 1 AGCAGGTCA CATCG GAGTGAGGG X 5 4 1 AGCTAGGTT GGCCC GAGTGAGGC X 5 4 1 AGTGTGGTC AGAGAG AAGAGAGGA X 5 4 1 AGTATGGTA ACAGCA GAGTGAGGG X 5 4 1 ATCCGTCTC TTCTG GTGTGAGGA X 5 4 1 AACAGTATT GCAAT GAGTGAGGG X 5 4 1 ATCAGCAGT GAACA AAGTGAGGA X 5 4 1 GGCCAAGTC AGCGG GAGTGAGGC X 5 4 1 GCCAGTGTT TCTCA GAGTGAGGT X 5 4 1 ATCAGGGCA GGCCAG GAGTGAGGG X 5 4 1 AGTAGATGC AGTTA GAGTGAGGT X 5 4 1 GGCCTGGTC AGGAGG GAGTGAGGG X 5 4 1 AGCAACTCA TTCTGT GAGTGAGGG X 5 4 1 GGGGGAGTC TTGCGG GAGTGAGGT X 5 4 1 ATCAGTCTA GCAGCA GAGTGAGGC X 5 4 1 AGTAGATGC ATAGG GAGTGAGGT X 5 4 1 ACCAGTGGT GGGGGT GAGTGAGGT X 5 4 1 GGCCTTGTC CCCTA GAGTGAGGG X 5 4 1 CTCATTGTC TTGCTG GAGTGAGGC X 5 4 1 AGTATGGTA AAAGGA GAGTGAGGG X 5 4 1 AGAGAGGTC AGGGTA GAGTGAGGG X 5 4 1 GGCCTGGTC AGATTT GAGTGAGGG X 5 4 1 TGTTGAGTC CGTATG GAGTGAGGG X 5 4 1 AGCACCACT GACAG GAGTGAGGG X 5 4 1 AAAACAGTC ATCCT GAGTGAGGG X 5 4 1 AACAGTATT AAGGA GAGTGAGGG X 5 4 1 GCCAACATC CACAT GAGTGAGGT X 5 4 1 GGCCAAGTC TCTCA GAGTGAGGC X 5 4 1 AAAACAGTC TTTCGA GAGTGAGGG X 5 4 1 AATCCCGTC ATGGA GAGTGAGGT X 6 4 2 GGTTACGTC CGGAA AAGTGAGGC X 6 4 2 AGTTACTTC TATAA AAGTGAGGG X 6 4 2 AGTTACTTC CCTCA AAGTGAGGG X 3 2 1 GGCATCGTC CACTC CAGTGAGGA X X 4 2 2 ATCAGGGTC CAGCT CAGTGAGGC X X 4 3 1 AGCTCAGTC ACTCCT GAGTGAGGG X X 4 3 1 AGCTCAGTC CTGGG GAGTGAGGG X X 4 3 1 AGCATGGTT TTCTG GAGTGAGGC X X 4 3 1 AGATGGGTC TTGCT GAGTGAGGC X X 4 3 1 AGATGGGTC TTGCT GAGTGAGGC X X 2 1 1 AGCAGAGTC AGGAT GAATGAGGA X 2 1 1 AGCAGAGTC ATGAA GATTGAGGA X 3 0 3 AGCAGCGTC TGAAAG TAGAGATGA X 3 0 3 AGCAGCGTC AGCTTC AAGTATGGA X 3 0 3 AGCAGCGTC AACATT TAGTAATGA X 3 0 3 AGCAGCGTC AACATT TAGTAATGA X 3 1 2 AGCAGTGTC TTAGGA AAGAGAGGA X 3 1 2 AGCAGCTTC AGATGG GAGAGAGAA X 3 1 2 AGCAGTGTC CAGCA AAGAGAGGA X 3 1 2 TGCAGCGTC AATGT GAGTGAAAA X 3 1 2 AGCAGTGTC AGGTAT GAGAGGGGA X 3 1 2 AGCAGCTTC AGGGA GAGTGTGGG X 3 1 2 AGCAGTGTC CTTGCC GAAGGAGGA X 3 1 2 AGCAGCTTC ATGAAG GAGAGAGAA X 3 1 2 AGCAGCGTG GAGGT GAGTGGGGT X 3 1 2 AGCAGCGTT ACTCAG GAGAGAGAA X 3 1 2 AGAAGCGTC ACTGA GAGTGAGTT X 3 1 2 AGCAGCATC TTGAG GGGTGAGGC X 3 1 2 AGCAGCGGC ACAAA GAGGGACGA X 3 1 2 AGCATCGTC TGAAG GGGTGAGCA X 3 1 2 AGCAGCTTC CACCA GAGGGAGTA X 3 1 2 AGCAGCGTT CTGTCT AAGTGAAGA X 3 1 2 AGCAGCATC TGCTTC GGGTGAGGC X 3 1 2 AGCAGGGTC GGGGA GGGTGAGAA X 3 1 2 AGCAGGGTC AGCTGG GAGTAAGAA X 3 1 2 AGCAGCGCC GGAAGA GAGCGAGGG X 3 1 2 AGCACCGTC CCTAA GACTGAGCA X 3 1 2 AGCAGAGTC ACAGCT GAATGAGGC X 3 1 2 AGCAGCGTG GACCCA AAGAGAGGA X 3 1 2 AGCAGGGTC CACAT GAGTCAGGG X 3 1 2 AGCAGGGTC GGGGTG GAGGGAGAA X 3 1 2 GGCAGGGTC CAGGTA GACTGAGGG X 3 1 2 AGCAGTGTC CTAAAG GAAGGAGGA X 3 1 2 AGCAGCCTC TTCTG TAATGAGGA X 3 1 2 AGCAGCGTT GGGAA GAGAGAGAA X 3 1 2 AGCAGCGAC AGGGCA GAATGAGGC X 3 1 2 AGCAGAGTC GAGCA AGGTGAGGA X 3 1 2 AGCAGCATC GAGTGG AAGTGGGGA X 3 2 1 AGCTGAGTC CAGAA GAGTGGGGA X 3 2 1 GGCAGTGTC AGTAG GTGTGAGGA X 3 2 1 AGCAACTTC AGAAT GAGTTAGGA X 3 2 1 AGCATCTTC AGCTA TAGTGAGGA X 3 2 1 GGCAGGGTC ACCCGA AAGTGAGGA X 3 2 1 AGCAGTGTG TGCCCA GAGTGAGTA X 3 2 1 AGCAGTGTA CCATGC GAGTGAGCA X 3 2 1 AGCTGGGTC TATTTG GAGTCAGGA X 3 2 1 AGCAGCGAG GTGGG GAGTGAGTA X 3 2 1 AGCAGCTTG GATTCA GAGTGAGAA X 3 2 1 AGCAGCAGC AACGAG GAGCGAGGA X 3 2 1 AGCACCATC TTTGAA AAGTGAGGA X 3 2 1 AGCAGAGTT TGAATT GAGTTAGGA X 3 2 1 GGCAGGGTC AAGGA AAGTGAGGA X 3 2 1 GGCAGTGTC CAGGAG GTGTGAGGA X 3 2 1 TGCAACGTC ACAAGT GAGAGAGGA X 3 2 1 AACAGTGTC TTTCAA AAGTGAGGA X 3 2 1 AGCAGTGTA GACCCA GAGTGAGCA X 3 2 1 AGCTGTGTC CCCTT GAGAGAGGA X 3 2 1 AGCAGCGGA GGTGGG GAGGGAGGA X 3 2 1 AACAGCTTC TCATT GAGTGAGTA X 3 2 1 AGTAGAGTC AGGCCT GAATGAGGA X 3 2 1 AGCAGCGAA GCCGG AAGTGAGGA X 3 2 1 AACTGCGTC CCAGG AAGTGAGGA X 3 2 1 AGAAGCCTC TGCTAT GAGTGAGGC X 3 2 1 AGCAGTGTG CAATG GAGTGAGTA X 3 2 1 AGTAGAGTC CCTGG GAGTGAGCA X 3 2 1 GGCAGTGTC ATGTGT GAGGGAGGA X 3 2 1 AGCACTGTC ACTGTT GAGTGATGA X 3 2 1 AGCTGGGTC TGGGAG GAGTCAGGA X 3 2 1 AGCAGCTTT CCAAGA GAGTGAGAA X 3 2 1 AGCAGTGTA GACCCA GAGTGAGCA X 3 2 1 GGCAGCGTG GGGATG CAGTGAGGA X 3 2 1 AGCAGCAGC AGAGG GAGCGAGGA X 3 2 1 AGTAGCTTC CCTCT GTGTGAGGA X 3 2 1 TGCGGCGTC TCCTGG GAGTGAAGA X 3 2 1 AACAGAGTC TGGCA GAGTGAGCA X 3 2 1 GGCAGCGGC CTGGG GAGTGTGGA X 3 2 1 AGCAGGCTC CTTGT TAGTGAGGA X 3 3 0 ATCACCATC ATACCT GAGTGAGGA X 3 3 0 AGCAGTTTA ATTCT GAGTGAGGA X 3 3 0 AACAGCAAC AAAAA GAGTGAGGA X 3 3 0 AGCTGAGTA GAATG GAGTGAGGA X 3 3 0 AGCAACCTG GGGCT GAGTGAGGA X 3 3 0 AGCAACCTG GAAAA GAGTGAGGA X 3 3 0 TGCAGGCTC CTGTG GAGTGAGGA X 3 3 0 CGCAGTATC CCACT GAGTGAGGA X 3 3 0 AGAAACATC AGATG GAGTGAGGA X 3 3 0 ACCTGTGTC TCCTG GAGTGAGGA X 3 3 0 GGCAGGGCC TCAAGG GAGTGAGGA X 3 3 0 AGAAACATC TAAGAG GAGTGAGGA X 3 3 0 AGGTGCATC CCTCA GAGTGAGGA X 3 3 0 GGCAGGGCC TTCTT GAGTGAGGA X 3 3 0 GGCAGCTGC TTTTT GAGTGAGGA X 3 3 0 AGCATGGCC CAGGAG GAGTGAGGA X 4 0 4 AGCAGCGTC TTCAGC AAGTGGAGG X 4 0 4 AGCAGCGTC TGGGGC AGTGGAGGA X 4 0 4 AGCAGCGTC TCATA GAGTTAACC X 4 0 4 AGCAGCGTC CCTGA AATTGTGCA X 4 1 3 AGCAACGTC AGGGAA GAGGGACCA X 4 1 3 AGCAGGGTC CACTCA GAGGGAGTC X 4 1 3 AGCAGCGTG TGGCT GTGTGTGGC X 4 1 3 AGCAGCGTT GGCTGA AACTGAGGT X 4 1 3 AGCAACGTC TCCAGG GACTGAAGC X 4 1 3 AGCAGGGTC ATTTAG GAGTGACAT X 4 1 3 AGCAGTGTC TTGTCA GAGTGTGTC X 4 1 3 AGCAACGTC CTCAAG GAGGCAAGA X 4 1 3 AGCATCGTC CACCTG GCGAGAGGC X 4 1 3 AGCAGCTTC TAACA AAGTGAGAC X 4 1 3 AGCAACGTC AGGGAG GAGAGGGCA X 4 1 3 AGCAGCGTT TTCAT GTGTGTGTA X 4 1 3 AGCAGCGTT TAACT GAGTGAAAG X 4 1 3 AGCAGGGTC AGCAG GAGGGAGTC X 4 1 3 AGCAGTGTC ATTAC GAGTGCGAC X 4 1 3 AGCAGTGTC AGTGC AAGTGCGGG X 4 1 3 AGCAGCTTC CATCG TGGTGTGGA X 4 1 3 GGCAGCGTC TAGGG GTGTGATAA X 4 1 3 AGCAGCTTC CGGTC GAGTGATTT X 4 1 3 AGCAGGGTC CGGCTT GTGTGCGGC X 4 1 3 AGCAGCGGC AAGAA GAGGGTGGT X 4 1 3 AGCAGCCTC ACTCA GAGTGGGAC X 4 1 3 AGCAACGTC TCCACA GAGACAGGC X 4 1 3 AGCAGCGTG GGGGGA GTGTGGGGG X 4 1 3 AGCAGGGTC TGCAGG GACTGAGAG X 4 1 3 AGCAGTGTC TTTTC CAGTAAGGT X 4 1 3 AGCAGCGGC AAGCAC AAGCAAGGA X 4 1 3 AGCAGCTTC CTCCAG GGGAGAGGT X 4 1 3 AGCAGCTTC GCCTGC TGGTGTGGA X 4 1 3 AGCAGCGAC TCACAC AAGTGAGAT X 4 1 3 AGCAGCGGC CCCAGC GAGTGTGTC X 4 1 3 AGCAGTGTC TGCAAC TAGTGAGCT X 4 1 3 AGCAGCGGC CTGGGG ACGAGAGGA X 4 1 3 AGCAGCGGC TGCCA GAGGGTGGT X 4 1 3 AGCAACGTC CATTCT GAGGCAAGA X 4 2 2 AGCATTGTC GGATTC TGGTGAGGA X 4 2 2 AGCATGGTC ACAAA GGGTGAGGT X 4 2 2 AGCAACATC ACAGA GAGAGAGGG X 4 2 2 AGCAATGTC CCTTG GAGTGTGGG X 4 2 2 AGCAGCTGC CAGAG GAGGGAGGC X 4 2 2 AGCTGGGTC CTAGA AAGTGAGGT X 4 2 2 AGCAGCTGC AGTGA GAGTGAGCT X 4 2 2 AGCATTGTC AATGA CAGTGAGAA X 4 2 2 AGCAAAGTC TAAGA GAGTGTGGC X 4 2 2 AGCAGGGTG GAGAA GAGCGAGGG X 4 2 2 ATCAACGTC CTTTGA GAGAAAGGA X 4 2 2 AGCAGCTTT TTTCC GAGTGAGAG X 4 2 2 GGCAGCGTT TCCTGT GAGCAAGGA X 4 2 2 AGCACCATC AGGAG GAGGGAGGG X 4 2 2 ATCAGAGTC TGCAG GCGTGAGGC X 4 2 2 AGCACCGGC CTCTTG GAGGGAGGT X 4 2 2 GGCAGGGTC AGTGG GAGTGAGTC X 4 2 2 AGCACCTTC TCCTGG TAGTGAGGC X 4 2 2 AGCGGTGTC ATCCAG GAGTGAGCG X 4 2 2 AGCAATGTC TATAA AAGTGAGGC X 4 2 2 AGCAGGGTA AGTAC AAGTGAGGC X 4 2 2 AGCAACGTG ATCGG GAGGGAGGG X 4 2 2 AGCAGGGTA GATGG GAGAGAGGG X 4 2 2 AGCAATGTC TGGGT GAGTGTGGG X 4 2 2 AGCAATGTC TGAAA TAGTGAGTA X 4 2 2 TGCAGAGTC AAGGAA GAGTGAGAT X 4 2 2 AGCATAGTC TCCTAG GAGAGAGGC X 4 2 2 AGCAGGGTA ATGGG GAGAGAGGG X 4 2 2 ATCACCGTC GAGGG GAGGGAGGG X 4 2 2 GGCAGCTTC GGTGTC CAGTGAGGC X 4 2 2 AGCTGGGTC TCATTG CAGTGAGGT X 4 2 2 AGCAACGTA CTGTT AAGTGAGAA X 4 2 2 AGCAAAGTC AAGAA GAGTGAAAA X 4 2 2 GGCAGGGTC TCTCA AAGTGAGGT X 4 2 2 TGCAGGGTC ATGCAA GTGTGAGGT X 4 2 2 AGCAAAGTC AGAGCT GAGTGAGCC X 4 2 2 GGCAGTGTC ATTTTT GAGTAAGGG X 4 2 2 AGCAGCTGC TGTGG GAGGGAGGC X 4 2 2 AGCAGCGGT GGTATC TAGTGAGGC X 4 2 2 AGCAACATC TGGAAC GAGTGAATA X 4 2 2 AGCAGTGTG ATCTT GAGTAAGGC X 4 2 2 GGCAGCTTC AGCAC CAGTGAGGC X 4 2 2 AGCAGAGTT GCTTAA GAGTGAGAG X 4 2 2 AGCACCTTC TGCCAA GAGTGAGAT X 4 2 2 AGCAGCTGC GGGCA GAGTGAGGT X 4 2 2 AGTAGAGTC TTTGTT GTGTGAGGT X 4 2 2 AGCATGGTC GTTGGG GGGTGAGGC X 4 2 2 AGCATTGTC TCTTGT GTGTGAGGT X 4 2 2 ATCAGAGTC AATTTG TAGTGAGGT X 4 2 2 AGCAGCTTA GAGGG GAGAGAGGT X 4 2 2 GACAGCGTC CTCCG GGGTGAGGC X 4 2 2 TGCAGAGTC AGCCCT GAGTGAGAT X 4 2 2 AGCAGAGTT GGAAG GAGTGAGAG X 4 2 2 AGCAGGGTA GGTCA GAGAGAGGG X 4 3 1 TGCAGTGAC TGTCCA GAGTGAGGC X 4 3 1 AGCAGAGGT GAGGT GAGTGAGGG X 4 3 1 AGCAGTTTA AATTT GAGTGAGGC X 4 3 1 AGAAAGGTC ATAAT GAGTGAGGG X 4 3 1 AGCACAATC CCAAAG GAGTGAGGC X 4 3 1 AGCAAAGGC AGGAG GAGTGAGGT X 4 3 1 AGCCACATC CCCTA GAGTGAGGT X 4 3 1 TGCTGGGTC TACAG GAGTGAGGC X 4 3 1 GGCAGTGTG AGCTG GAGTGAGGG X 4 3 1 AGTAGTGTG CTGAA GAGTGAGGG X 4 3 1 TGCATGGTC AGAGGT GAGTGAGGG X 4 3 1 AGCATAGTT TAGGAT CAGTGAGGA X 4 3 1 AGCAGCAGG ATGAGA GAGTGAGGC X 4 3 1 AGCACCATT AAATTG GAGTGAGGC X 4 3 1 ATCAGGGTT AAGCA GAGTGAGGG X 4 3 1 AGCAAAGTG GAGAG GAGGGAGGA X 4 3 1 AGCAACACC AATGAA GAGTGAAGA X 4 3 1 GGCAGTGGC TCTGT GAGTGAGGT X 4 3 1 AGTATCGGC TGTGGT GAGTGAGGG X 4 3 1 GGCAGCTCC GCCTCC GAGTGAGGG X 4 3 1 AGCAAAGGC TGGGTG GAGTGAGGT X 4 3 1 AGCAAGTTC CACTG GAGTGTGGA X 4 3 1 AGCAAAGGC AGTCA GAGTGAGGG X 4 3 1 CGCAGCAAC GCTCTG GAGTGAGGC X 4 3 1 GGCAGCGGT TGGGG GAGTGAGGC X 4 3 1 AGCAACTGC TTTTA GAGTGAGCA X 4 3 1 AGAAGAGTA AAGCA GAGTGAGGT X 4 3 1 AGCAACATA ATAACA GAGTGAGGT X 4 3 1 CGCACCTTC CTGTAT GAGTGAGGC X 4 3 1 GTCCGCGTC GCCCA GAGTGAGAA X 4 3 1 GGCAGTGTG CTTGAT GAGTGAGGG X 4 3 1 CCCACCGTC CTAAAG AAGTGAGGA X 4 3 1 AACAACGTG AAACCA GAGTGAGGC X 4 3 1 AGCAACCAC AAAAA AAGTGAGGA X 4 3 1 AGCCCCTTC AGCATA GAGTGAGGG X 4 3 1 AGCCGCTGC AGCAGG GAGTGAGGT X 4 3 1 AGCCGCTGC AGCAGG GAGTGAGGT X 4 3 1 AGCCGCTGC AGCAGG GAGTGAGGT X 4 3 1 AGCCGCTGC AGCAGG GAGTGAGGT X 4 3 1 AGAGGGGTC TGCAG GAGTGAGGG X 4 3 1 AGCAAAGGC AAATA GAGTGAGGG X 4 3 1 GGCAACTTC CAAGA AAGTGAGGA X 4 3 1 GCCAGCTTC CATACA GAGTGAGGC X 4 3 1 AGAAGGGTG ATTAG GAGTGAGGC X 4 3 1 AGCTACGAC TCAGGA GAGTGAGGT X 4 3 1 AGCAAGGTG GGCGG GAGTGAGGG X 4 3 1 AGGAGAGTT AGAAGA GAGTGAGGT X 4 3 1 TGCTCCGTC CTGGCT GAGTGAGGT X 4 3 1 AGCACTGTT TGCCC GAGTGAGGC X 4 3 1 AGTACCATC AGGGCT GAGTGAGGC X 4 3 1 AGCAGCAGG GCAGT GAGTGAGGC X 4 3 1 GGCAGGGAC CATAT GAGTGAGGC X 4 3 1 AGCAAGGTT CCCCG GAGTGAGTA X 4 3 1 AGCATGGGC AGGGG GAGTGAGGC X 4 3 1 AGCTGAGTA GCTAA GAGTGAGGC X 4 3 1 AGCGACTTC ATATCT GAGTGAGGT X 4 3 1 AGGAGAGTT TAAAG GAGTGAGGT X 4 3 1 GACAGCATC AGTCTG GAGTGAGGG X 4 3 1 AGCAACTCC ATTTC GAGTGAGGC X 4 3 1 AGTCGCTTC ACTTTG GAGTGAGAA X 4 3 1 AGTAACATC TTTACT GAGGGAGGA X 4 3 1 AGCAACTGC AATGGT GAGTGAGCA X 4 3 1 AGCATTGTG CTAGG CAGTGAGGA X 4 3 1 AGAAAAGTC TTGAAG GAGTGAGGG X 4 3 1 GGCAGTGTA GGGAG GAGTGAGGT X 4 3 1 AGCAAGGTA AAGGAG GAGTGAGGT X 4 3 1 AGCATCTGC AGATG GAGTGAGGC X 4 3 1 TGCATAGTC TTGGG GAGTGAGGG X 4 3 1 AGAAGGGTG AGGTGG GAGTGAGGC X 4 3 1 AGCCGAGTG GTTAA GAGTGAGGG X 4 3 1 CTCAGGGTC ATTAGT GAGTGAGGG X 4 3 1 AACAGGGTT GGCCT GAGTGAGGC X 4 3 1 AGCCTAGTC ACACCT GAGTGAGGG X 4 3 1 AGCAATGTT TTGCT GAGTGAGAA X 4 3 1 AGCAGCAAA TCTGCT GAGTGAGGT X 4 3 1 AGCAGTCCC TGCCCA GAGTGAGGC X 4 3 1 TGCAATGTC TTTGA GAGTGAGGT X 4 3 1 TGCAGGTTC TTTGG GAGTGAGGG X 4 3 1 AGCTAAGTC TGTAGG CAGTGAGGA X 4 3 1 AGCATAGTT GGGAG CAGTGAGGA X 4 3 1 AGCATGGTA GAGACT GAGTGAGGG X 4 3 1 AGCAAGGAC TGGGCT GAGTGAGGC X 4 3 1 AGGTGGGTC CCCAGA GAGTGAGGC X 4 3 1 AGCAGCTGT CAATCA GAGTGAGGC X 4 3 1 TGCATGGTC CTGGAG GAGTGAGGG X 4 3 1 AGCATAGTA CTTAA GAGTGAGGG X 4 3 1 AGCAAGGTA ATTAG GAGTGAGTA X 4 3 1 TGCACCTTC ATGCCT GAGTGAGGG X 4 3 1 AGCACCGAG GTCGGA GAGTGAGGG X 4 3 1 TGGAGAGTC AGCAG GAGTGAGTA X 4 3 1 AGAAGAGTT AGGTGG GAGTGAGGT X 4 3 1 ATCAGGGTT AGGAT GAGTGAGGG X 4 3 1 GGCAGTGCC CAGCAG GAGTGAGGC X 4 3 1 AGTAAGGTC TTAAA TAGTGAGGA X 4 3 1 AGCAGCAGG CCAGT GAGTGAGGC X 4 4 0 AGCCATGTG CAAGT GAGTGAGGA X 4 4 0 GGTAGTGTT ATGAAT GAGTGAGGA X 4 4 0 TACAAAGTC GATGA GAGTGAGGA X 4 4 0 AGCCATGTA CATGT GAGTGAGGA X 4 4 0 GACTGGGTC TGTCAT GAGTGAGGA X 4 4 0 AGCACAGCA GATGA GAGTGAGGA X 4 4 0 TGAATAGTC TTGGAA GAGTGAGGA X 4 4 0 GTCAGGTTC ACACAT GAGTGAGGA X 4 4 0 GGTAAAGTC TGGTCA GAGTGAGGA X 4 4 0 AGTATAGTG GCAGA GAGTGAGGA X 4 4 0 ATGGGGGTC AGAGGG GAGTGAGGA X 4 4 0 CCCAAAGTC GTAAG GAGTGAGGA X 4 4 0 CAAATCGTC TACAT GAGTGAGGA X 4 4 0 AATAAGGTC ATAGCA GAGTGAGGA X 4 4 0 AGTATAGTT CAGAT GAGTGAGGA X 4 4 0 AGAGAGGTC AAGGA GAGTGAGGA X 4 4 0 TGGTGAGTC ACCAC GAGTGAGGA X 4 4 0 TGCCTGGTC ACTTGG GAGTGAGGA X 4 4 0 AGCCATGTG GGAAG GAGTGAGGA X 4 4 0 AACAAGGTT CGCAGA GAGTGAGGA X 4 4 0 AGCAATTTA TGTACA GAGTGAGGA X 4 4 0 AGGCATGTC TCAGCA GAGTGAGGA X 4 4 0 TACAAAGTC CTTAG GAGTGAGGA X 4 4 0 AATAAGGTC AGAGAG GAGTGAGGA X 4 4 0 AATAAAGTC AGATAG GAGTGAGGA X 4 4 0 AATAAGGTC AGATAG GAGTGAGGA X 4 4 0 AATAAGGTC AAATAG GAGTGAGGA X 4 4 0 AATAAGGTC AGATG GAGTGAGGA X 4 4 0 AATAAGGTC AGATAG GAGTGAGGA X 4 4 0 AGCACAGCA GGCAG GAGTGAGGA X 4 4 0 GGAAAGGTC AGTTAT GAGTGAGGA X 4 4 0 AGCCATTTC AACAA GAGTGAGGA X 4 4 0 AATAAGGTC ACGGTG GAGTGAGGA X 4 4 0 ATCAGCACT TCAGA GAGTGAGGA X 4 4 0 GGTGGGGTC ATGGA GAGTGAGGA X 4 4 0 CACACAGTC AGTGTA GAGTGAGGA X 4 4 0 AATATTGTC TCTGT GAGTGAGGA X 4 4 0 GGAATAGTC TGGTTA GAGTGAGGA X 4 4 0 AGCAACAAT CGTAC GAGTGAGGA X 4 4 0 AATAAGGTC ACAGTG GAGTGAGGA X 4 4 0 GACTGTGTC CTTCA GAGTGAGGA X 4 4 0 AATAAAGTC AGATAG GAGTGAGGA X 4 4 0 AATAAGGTC AGAGAG GAGTGAGGA X 4 4 0 AATAAGGTC AGACAA GAGTGAGGA X 4 4 0 AATAAGGTC AGATAG GAGTGAGGA X 4 4 0 AATAAGGTC AGATG GAGTGAGGA X 5 1 4 AGCAGCTTC CCCTG CAGAAAGGT X 5 2 3 GGCAACGTC ATCTC TAGTGAGAC X 5 2 3 AGCAGTTTC TTTTAC TTGTGAGGG X 5 2 3 AGCAGTTTC AGTATC TTGTGAGGG X 5 2 3 AGCAGCAGC CGAAC GAGGGAGAT X 5 2 3 AGCAGCAGC CCAGG GAGGGAGAT X 5 2 3 AGCAACTTC TCTAA TTGTGAGGT X 5 2 3 AGCAACTTC CACAG TTGTGAGGT X 5 2 3 AGCAAGGTC AGTGA TAGTGAATA X 5 2 3 AGCAGTTTC GGTGTT TTGTGAGGG X 5 2 3 AGCAGCAGC AGGAA GAGGGAGAT X 5 2 3 AGCATTGTC TTAGA AAGTAAGGG X 5 3 2 AGCCCAGTC TCAGG GAGTGAGAG X 5 3 2 AGCTACATC TGCATT GAGTGAGTC X 5 3 2 AGCATGGTT TGAAAG GAGTGAGCC X 5 3 2 GACAGGGTC CACTTG GAGTGAGTC X 5 3 2 ATCCTCGTC CTGCA GAGTGAGTC X 5 3 2 CAGAGCGTC CAGGT GAGTGAGTC X 5 3 2 AGCAAAGGC CTGAAG GAGTAAGGG X 5 3 2 AGCATCGAT TAAAA GAGTGAGAG X 5 3 2 ATCATGGTC ACTTT GAGGGAGGG X 5 3 2 AGCCCAGTC CCCCTA GAGTGAGAG X 5 3 2 TGCATAGTC AATTT GAGTGAGAT X 5 3 2 AGCCATGTC AGCTT GAGGGAGGT X 5 3 2 AGCATTGTA GGGGAC GAGTGTGGT X 5 3 2 ATCATGGTC CAGGA GAGGGAGGG X 5 3 2 AGCAAAGGC CAAGT GAGTAAGGG X 5 3 2 ATAAGAGTC ATGCAG GAGTGAGTG X 5 3 2 AGCCATGTC CCAAGG GAGGGAGGT X 5 3 2 AGCAAAGGC AATGA GAGTAAGGG X 5 3 2 AGCCCAGTC AGGAT GAGTGAGAG X 5 4 1 TTCCACGTC AACAT GAGTGAGGG X 5 4 1 AGTCAGGTC CCCACA GAGTGAGGT X 5 4 1 CTGAGGGTC GGTAG GAGTGAGGC X 5 4 1 ATGACAGTC TATGCA GAGTGAGGC X 5 4 1 AACAGTCTA CCTGA GAGTGAGGC X 5 4 1 CTCAGTTTC CTGAG GAGTGAGGG X 5 4 1 AGTCAGGTC TTCCAT GAGTGAGGG X 5 4 1 GTGGGCGTC CACTAA GAGTGAGGC X 5 4 1 GGTGGGGTC CTTGAA GAGTGAGGC X 5 4 1 AGTTAAGTC TCTAGA GAGTGAGGG X 5 4 1 TTCACCTTC CACCAT GAGTGAGGC X 5 4 1 TCCTGAGTC TTGGTA GAGTGAGGC X 5 4 1 ATAATAGTC TCCAT GAGTGAGGC X 5 4 1 AGCAAAGGT GGGGTG GAGTGAGGT X 5 4 1 AGTTTAGTC CTTGG GAGTGAGGT X 5 4 1 ACAAAGGTC CTCCA GAGTGAGGC X 5 4 1 TGCAGTCCC AATCA GAGTGAGGT X 5 4 1 AGTCATGTC GTTAA GAGTGAGGC X 5 4 1 CACCACGTC AAGGTA GAGAGAGGA X 5 4 1 CTCAGTTTC AAAAGC GAGTGAGGG X 5 4 1 GAAAGTGTC CAAGTG GAGTGAGGC X 5 4 1 GGGTGGGTC TAGAGG GAGTGAGGT X 5 4 1 AGAGTTGTC CCCCAA GAGTGAGGC X 6 4 2 AGAAGGGGT AGGAG GAGTGAGAG X 3 1 2 AGCAGAGTC ATATT GAGTCAGGG X 3 3 0 ACCATCTTC ATCAG GAGTGAGGA X 4 2 2 AGGAACGTC TCCAA GGGTGAGGG X 4 2 2 AGCACCTTC AGAGG GAGTGTGGC X 4 2 2 GGCAGGGTC GGTCA GAGTGAGAG X 4 2 2 GGCAGGGTC ACAGGT GAGTGAGAG X 4 2 2 AGCACAGTC AAGCT GAGGGAGGT X 4 2 2 GGCAGGGTC TAGGCA GAGTGAGAG X 4 2 2 AGCAAGGTC TACTCG GGGTGAGGC X 4 3 1 AGCAAGTTC CGTTAA GAGTGAGGT X 4 3 1 AGCAGTTTT TGCAGT GAGTGAGGC X 2 1 1 AGCTGCGTC ACATG GACTGAGGA X 3 1 2 AGCAGGGTC TGAGCT GTGTGGGGA X 3 1 2 AGCAGGGTC AGCTG GTGTGGGGA X 3 2 1 AGAAGCCTC AAGGAT GAGTGAGGT X 3 2 1 AGAAGCCTC ATAAGT GAGTGAGGT X 3 3 0 AGCATTTTC AATTT GAGTGAGGA X 4 0 4 AGCAGGGTC CCTCC GACACTGGA X 4 1 3 AGCAGTGTC ACCGAC AGGTGAGGC X 4 1 3 AGCAGTGTC TGGGA GAGGGTAGA X 4 2 2 AGCAACTTC TTCCT GGGTGAGGC X 4 3 1 AGCCCGGTC TGAAAG GAGTGAAGA X 4 3 1 AGTAACTTC TGAGTG GAGTGAGGC X 4 3 1 AGTAACTTC AAAAT GAGTGAGGC X 4 3 1 ACCTGCTTC AAAGT GAGTGAGGG X 4 3 1 AGCATTTTC CCCCTA AAGTGAGGA X 4 3 1 AGTAACTTC AGTATA GAGTGAGGC X 4 3 1 AGCAATGTT TGAGT GAGTGATGA X 4 3 1 AGCATTTTC CTTTA AAGTGAGGA X 4 3 1 AGCCACGGC TGCCTG GAGTGAGGG X 4 4 0 CCTAGAGTC CAGGA GAGTGAGGA X 5 4 1 ATCATAGTG ACCAC GAGTGAGGC X 

What is claimed is:
 1. A method comprising: (a) providing a dimeric site-specific nuclease that cuts one or more double-stranded target sites of a double-stranded nucleic acid and creates a 5′ overhang on the double-stranded nucleic acid, wherein the dimeric site-specific nuclease comprises two monomers, each of which comprises a site-specific DNA binding domain and a cleavage domain; wherein each of the one or more double-stranded target sites of the dimeric site-specific nuclease comprises a 5′-[left-half site]-[spacer sequence]-[right-half site]-3′ (LSR) structure, and wherein the left-half site comprises a nucleic acid sequence that is bound by the site-specific DNA binding domain of one monomer of the dimeric site-specific nuclease and the right-half site comprises a nucleic acid sequence that is bound by the site-specific DNA binding domain of other monomer of the dimeric site-specific nuclease, and wherein the spacer sequence comprises a cleavage site of the dimeric site-specific nuclease; (b) contacting the dimeric site-specific nuclease of step (a) with a library of candidate nucleic acid molecules, wherein each of the candidate nucleic acid molecules of the library comprises a concatemer containing multiple copies of the same DNA sequences linked in a series, wherein each copy of the same DNA sequences comprises one of the double-stranded target sites of the dimeric site-specific nuclease and a constant insert sequence, wherein the contacting step is done under conditions suitable for the dimeric site-specific nuclease to cut the candidate nucleic acid molecules once, twice, or multiple times, thereby releasing double-stranded fragments with 5′ overhangs from the concatemer, whereby each strand of the double-stranded fragments has a 5′ overhang, each of the double-stranded fragments comprises a first strand comprising the constant insert sequence flanked at the 5′ end by the right-half site and a part of the spacer sequence and a complementary strand of each of the double stranded fragments comprises the constant insert sequence flanked at the 5′ end by the left-half site and a part of the spacer sequence, wherein the double-stranded fragments with 5′ overhangs are released when the candidate nucleic acid molecules are cut twice by the dimeric site-specific nuclease; (c) filling in the 5′ overhangs of the double-stranded fragments released in step (b), thereby creating fragments with blunt ends; and (d) identifying the one or more double-stranded target sites of the dimeric site-specific nuclease of the double-stranded fragments with 5′ overhangs by determining the sequence of the fragments with blunt ends from step (c).
 2. The method of claim 1, wherein step (d) further comprises ligating sequencing adapters to the blunt ends of the fragments with blunt ends.
 3. The method of claim 2, wherein the method further comprises amplifying the fragments with blunt ends via a polymerase chain reaction (PCR) after said ligating the sequencing adapters to the blunt ends of the fragments with blunt ends.
 4. The method of claim 1 further comprising a step of enriching the double-stranded fragments with 5′ overhangs released in step (b).
 5. The method of claim 4, wherein the step of enriching the double-stranded fragments with 5′ overhangs comprises a size fractionation of the double-stranded fragments with 5′ overhangs.
 6. The method of claim 1, further comprising compiling the one or more double-stranded target sites of the dimeric site-specific nuclease identified in step (d), thereby generating a double-stranded nuclease target site profile.
 7. The method of claim 1, wherein the dimeric site-specific nuclease is a therapeutic nuclease which cuts the one or more double-stranded target sites in a gene associated with a disease.
 8. The method of claim 7 further comprising determining a maximum concentration of the therapeutic nuclease at which the therapeutic nuclease cuts only one of the double-stranded nuclease target sites, and does not cut more than 10, more than 5, more than 4, more than 3, more than 2, more than 1 of the double-stranded target sites in the candidate nucleic acid molecules.
 9. The method of claim 1, wherein the cleavage domain is a non-specific cleavage domain.
 10. The method of claim 1, wherein the dimeric site-specific nuclease cleaves a target sequence upon dimerization of the cleavage domain of each of the two monomers.
 11. The method of claim 1, wherein the site-specific DNA binding domain comprises a zinc finger.
 12. The method of claim 11, wherein the dimeric site-specific nuclease is a Zinc Finger Nuclease.
 13. The method of claim 1, wherein the site-specific DNA binding domain comprises a Transcriptional Activator-Like Element.
 14. The method of claim 13, wherein the dimeric site-specific nuclease is a Transcriptional Activator-Like Element Nuclease (TALEN).
 15. The method of claim 1, wherein the cleavage domain is a cleavage domain of an endonuclease.
 16. The method of claim 15, wherein the endonuclease is FokI.
 17. The method of claim 1, wherein the dimeric site-specific nuclease is a homing nuclease. 